Analysis of the ospC regulatory element controlled by the RpoN-RpoS regulatory pathway in Borrelia burgdorferi.

Outer surface lipoprotein C (OspC) is a key virulence factor of Borrelia burgdorferi. ospC is differentially regulated during borrelial transmission from ticks to rodents, and such regulation is essential for maintaining the spirochete in its natural enzootic cycle. Recently, we showed that the expression of ospC in B. burgdorferi is governed by a novel alternative sigma factor regulatory network, the RpoN-RpoS pathway. However, the precise mechanism by which the RpoN-RpoS pathway controls ospC expression has been unclear. In particular, there has been uncertainty regarding whether ospC is controlled directly by RpoS (sigma(s)) or indirectly through a transactivator (induced by RpoS). Using deletion analyses and genetic complementation in an OspC-deficient mutant of B. burgdorferi, we analyzed the cis element(s) required for the expression of ospC in its native borrelial background. Two highly conserved upstream inverted repeat elements, previously implicated in ospC regulation, were not required for ospC expression in B. burgdorferi. Using similar approaches, a minimal promoter that contained a canonical -35/-10 sequence necessary and sufficient for sigma(s)-dependent regulation of ospC was identified. Further, targeted mutagenesis of a C at position -15 within the extended -10 region of ospC, which is postulated to function like the strategic C residue important for Esigma(s) binding in Escherichia coli, abolished ospC expression. The minimal ospC promoter also was responsive to coumermycin A(1), further supporting its sigma(s) character. The combined data constitute a body of evidence that the RpoN-RpoS regulatory network controls ospC expression by direct binding of sigma(s) to a sigma(s)-dependent promoter of ospC. The implication of our findings to understanding how B. burgdorferi differentially regulates ospC and other ospC-like genes via the RpoN-RpoS regulatory pathway is discussed.

Essential role for OspA/B in the life cycle of the Lyme disease spirochete.

The molecular basis of how Borrelia burgdorferi (Bb), the Lyme disease spirochete, maintains itself in nature via a complex life cycle in ticks and mammals is poorly understood. Outer surface (lipo)protein A (OspA) of Bb has been the most intensively studied of all borrelial molecular constituents, and hence, much has been speculated about the potential role(s) of OspA in the life cycle of Bb. However, the precise function of OspA (along with that of its close relative and operonic partner, outer surface [lipo]protein B [OspB]) heretofore has not been directly determined, due primarily to the inability to generate an OspA/B-deficient mutant from a virulent strain of Bb. In this study, we created an OspA/B-deficient mutant of an infectious human isolate of Bb (strain 297) and found that OspA/B function was not required for either Bb infection of mice or accompanying tissue pathology. However, OspA/B function was essential for Bb colonization of and survival within tick midguts, events crucial for sustaining Bb in its natural enzootic life cycle.

The response regulator Rrp2 is essential for the expression of major membrane lipoproteins in Borrelia burgdorferi.

Borrelia burgdorferi (Bb), the agent of Lyme disease, exists in nature through a complex enzootic life cycle that involves both ticks and mammals. As Bb transitions between its two diverse niches, profound adaptive changes occur that are reflected in differential patterns of gene expression, particularly involving lipoprotein genes. Using a mutagenesis approach, we show that Rrp2 (gene BB0763), one of the proteins predicted by the Bb genome (www.tigr.org) to be a response regulator of a two-component sensory transduction system, is a pivotal regulator governing the expression of major membrane lipoproteins such as OspC, DbpA, and Mlp8, as well as many other mammalian infection-associated immunogens of Bb. Sequence analysis additionally suggested that Rrp2 is a bacterial enhancer-binding protein, essential for sigma54-dependent gene activation. Mutagenesis of a key amino acid residue within a putative activation domain revealed that Rrp2 controlled lipoprotein expression by governing the expression of the alternative sigma-factor sigmas in a sigma54-dependent manner. We therefore propose a signal transduction pathway involving Rrp2, sigma54, and sigmas, which in concert control the expression of key lipoproteins and other infection-associated immunogens in Bb.