e Borrelia burgdorferi, the Lyme disease spirochete, couples environmental sensing and gene regulation primarily via the Hk1/ Rrp1 two-component system (TCS) and Rrp2/RpoN/RpoS pathways. Beginning with acquisition, we reevaluated the contribution of these pathways to spirochete survival and gene regulation throughout the enzootic cycle. Live imaging of B. burgdorferi caught in the act of being acquired revealed that the absence of RpoS and the consequent derepression of tick-phase genes impart a Stay signal required for midgut colonization. In addition to the behavioral changes brought on by the RpoS-off state, acquisition requires activation of cyclic di-GMP (c-di-GMP) synthesis by the Hk1/Rrp1 TCS; B. burgdorferi lacking either component is destroyed during the blood meal. Prior studies attributed this dramatic phenotype to a metabolic lesion stemming from reduced glycerol uptake and utilization. In a head-to-head comparison, however, the B. burgdorferi ⌬glp mutant had a markedly greater capacity to survive tick feeding than B. burgdorferi ⌬hk1 or ⌬rrp1 mutants, establishing unequivocally that glycerol metabolism is only one component of the protection afforded by c-di-GMP. Data presented herein suggest that the protective response mediated by c-di-GMP is multifactorial, involving chemotactic responses, utilization of alternate substrates for energy generation and intermediary metabolism, and remodeling of the cell envelope as a means of defending spirochetes against threats engendered during the blood meal. Expression profiling of c-di-GMP-regulated genes through the enzootic cycle supports our contention that the Hk1/Rrp1 TCS functions primarily, if not exclusively, in ticks. These data also raise the possibility that c-di-GMP enhances the expression of a subset of RpoS-dependent genes during nymphal transmission.
Borrelia burgdorferi, the causative agent of Lyme disease, is maintained in nature within an enzootic cycle that involves an arthropod vector and vertebrate reservoir hosts, typically, small rodents and birds (1). In the northeastern United States, the primary vector for B. burgdorferi is the black-legged deer tick, Ixodes scapularis (2, 3). Because B. burgdorferi cannot be passaged transovarially, naive larvae acquire spirochetes by feeding on infected reservoir hosts. Successful colonization of the vector requires B. burgdorferi to establish an intimate association with rapidly differentiating, highly endocytic midgut epithelial cells (4-6). In order to accomplish this feat, spirochetes must resist deleterious substances within the midgut lumen, such as host-and tick-derived innate immune effector molecules, reactive oxygen species (ROS), and salivary enzymes imbibed from the feeding site (4, 7-11). At the same time, B. burgdorferi also must alter its metabolic machinery to exploit the availability of alternative carbon sources (e.g., glycerol, N-acetylglucosamine [GlcNAc], chitobiose) as the supply of ingested glucose diminishes (12-15). During nymphal transmission, spirochetes are almost certai...
