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Stage‐specific global alterations in the transcriptomes of L yme disease spirochetes during tick feeding and following mammalian host adaptation
Author(s) -
Iyer Radha,
Caimano Melissa J.,
Luthra Amit,
Axline David,
Corona Arianna,
Iacobas Dumitru A.,
Radolf Justin D.,
Schwartz Ira
Publication year - 2015
Publication title -
molecular microbiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.857
H-Index - 247
eISSN - 1365-2958
pISSN - 0950-382X
DOI - 10.1111/mmi.12882
Subject(s) - biology , borrelia burgdorferi , enzootic , transcriptome , tick , lyme disease , ixodes , virulence , microbiology and biotechnology , ixodes scapularis , gene , chemotaxis , gene expression , genetics , virology , virus , receptor , antibody
Summary B orrelia burgdorferi , the agent of L yme disease, is maintained in nature within an enzootic cycle involving a mammalian reservoir and an I xodes sp. tick vector. The transmission, survival and pathogenic potential of B . burgdorferi depend on the bacterium's ability to modulate its transcriptome as it transits between vector and reservoir host. Herein, we employed an amplification‐microarray approach to define the B . burgdorferi transcriptomes in fed larvae, fed nymphs and in mammalian host‐adapted organisms cultivated in dialysis membrane chambers. The results show clearly that spirochetes exhibit unique expression profiles during each tick stage and during cultivation within the mammal; importantly, none of these profiles resembles that exhibited by in vitro grown organisms. Profound shifts in transcript levels were observed for genes encoding known or predicted lipoproteins as well as proteins involved in nutrient uptake, carbon utilization and lipid synthesis. Stage‐specific expression patterns of chemotaxis‐associated genes also were noted, suggesting that the composition and interactivities of the chemotaxis machinery components vary considerably in the feeding tick and mammal. The results as a whole make clear that environmental sensing by B . burgdorferi directly or indirectly drives an extensive and tightly integrated modulation of cell envelope constituents, chemotaxis/motility machinery, intermediary metabolism and cellular physiology. These findings provide the necessary transcriptional framework for delineating B . burgdorferi regulatory pathways throughout the enzootic cycle as well as defining the contribution(s) of individual genes to spirochete survival in nature and virulence in humans.