Find in Library

<i>Borreliella</i> (syn. <i>Borrelia</i>) <i>burgdorferi</i> is a spirochete bacterium that causes tick-borne Lyme disease. Along its lifecycle <i>B. burgdorferi</i> develops several pleomorphic forms with unclear biological and medical relevance. Surprisingly, these morphotypes have never been compared at the global transcriptome level. To fill this void, we grew <i>B. burgdorferi</i> spirochete, round body, bleb, and biofilm-dominated cultures and recovered their transcriptomes by RNAseq profiling. We found that round bodies share similar expression profiles with spirochetes, despite their morphological differences. This sharply contrasts to blebs and biofilms that showed unique transcriptomes, profoundly distinct from spirochetes and round bodies. To better characterize differentially expressed genes in non-spirochete morphotypes, we performed functional, positional, and evolutionary enrichment analyses. Our results suggest that spirochete to round body transition relies on the delicate regulation of a relatively small number of highly conserved genes, which are located on the main chromosome and involved in translation. In contrast, spirochete to bleb or biofilm transition includes substantial reshaping of transcription profiles towards plasmids-residing and evolutionary young genes, which originated in the ancestor of <i>Borreliaceae</i>. Despite their abundance the function of these <i>Borreliaceae</i>-specific genes is largely unknown. However, many known Lyme disease virulence genes implicated in immune evasion and tissue adhesion originated in this evolutionary period. Taken together, these regularities point to the possibility that bleb and biofilm morphotypes might be important in the dissemination and persistence of <i>B. burgdorferi</i> inside the mammalian host. On the other hand, they prioritize the large pool of unstudied <i>Borreliaceae</i>-specific genes for functional characterization because this subset likely contains undiscovered Lyme disease pathogenesis genes.