A Dual Luciferase Reporter System for B. burgdorferi Measures Transcriptional Activity during Tick-Pathogen Interactions.

Philip P Adams,Mollie W Jewett,Carlos Flores Avile

doi:10.3389/fcimb.2017.00225

Philip P Adams, Mollie W Jewett + Show 1 more

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https://doi.org/10.3389/fcimb.2017.00225

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Abstract

Knowledge of the transcriptional responses of vector-borne pathogens at the vector-pathogen interface is critical for understanding disease transmission. Borrelia (Borreliella) burgdorferi, the causative agent of Lyme disease in the United States, is transmitted by the bite of infected Ixodes sp. ticks. It is known that B. burgdorferi has altered patterns of gene expression during tick acquisition, persistence and transmission. Recently, we and others have discovered in vitro expression of RNAs found internal, overlapping, and antisense to annotated open reading frames in the B. burgdorferi genome. However, there is a lack of molecular genetic tools for B. burgdorferi for quantitative, strand-specific, comparative analysis of these transcripts in distinct environments such as the arthropod vector. To address this need, we have developed a dual luciferase reporter system to quantify B. burgdorferi promoter activities in a strand-specific manner. We demonstrate that constitutive expression of a B. burgdorferi codon-optimized Renilla reniformis luciferase gene (rlucBb) allows normalization of the activity of a promoter of interest when fused to the B. burgdorferi codon-optimized Photinus pyralis luciferase gene (flucBb) on the same plasmid. Using the well characterized, differentially regulated, promoters for flagellin (flaBp), outer surface protein A (ospAp) and outer surface protein C (ospCp), we document the efficacy of the dual luciferase system for quantitation of promoter activities during in vitro growth and in infected ticks. Cumulatively, the dual luciferase method outlined herein is the first dual reporter system for B. burgdorferi, providing a novel and highly versatile approach for strand-specific molecular genetic analyses.

Highlights

Vector-borne illnesses account for 17% of worldwide infectious diseases, amounting to over one billion cases yearly (World Health Organization, 2016)
Codon usage in B. burgdorferi is biased (Fraser et al, 1997; Nakamura et al, 2000), as the A/T nucleotide frequency is at 71.8% across the genome (Fraser burgdorferi codon optimized Photinus pyralis luciferase, an upstream ribosome binding site (RBS) and a unique BlgII restriction site (Blevins et al, 2007)
The plasmid pJSB175 was generated by addition of the flaBp promoter upstream of flucBb in pJSB161 (Blevins et al, 2007). (B) The B. burgdorferi codon optimized Renilla reniformis luciferase gene under the control of the flaB promoter was added to pJSB161, generating the B. burgdorferi dual luciferase shuttle vector, pCFA701

Summary

Introduction

Vector-borne illnesses account for 17% of worldwide infectious diseases, amounting to over one billion cases yearly (World Health Organization, 2016). Ticks are notorious for delivering a diversity of infectious agents to their hosts during the blood meal. Of these pathogens the Borrelia burgdorferi sensu lato complex or Borreliella genus (Adeolu and Gupta, 2014), the spirochete group. Hatched larval ticks are not colonized with B. burgdorferi, as there is currently no evidence to support transovarial transmission of the pathogen (Rollend et al, 2013). The infected nymphs take a single blood meal from a vertebrate followed by morphogenesis to adults. B. burgdorferi migrate from the midgut to the tick salivary glands and are transmitted to the vertebrate host, maintaining the spirochete in its enzootic cycle (Radolf et al, 2012). It has been proposed that B. burgdorferi undergoes three major tick-related events that require complex genetic regulation: acquisition, persistence, and transmission (Iyer et al, 2015; Caimano et al, 2016)

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