Characterization of a manganese-dependent regulatory protein, TroR, from Treponema pallidum

Abstract

Genome sequence analysis of Treponema pallidum , the causative agent of syphilis, suggests that this bacterium has a limited iron requirement with few, if any, proteins that require iron. Instead, T. pallidum may use manganese-dependent enzymes for metabolic pathways. This strategy apparently alleviates the necessity of T. pallidum to acquire iron from the host, thus overcoming iron limitation, which is a primary host defense. Interestingly, a putative metal-dependent regulatory protein, TroR, which has homology with the diphtheria toxin regulatory protein, DtxR, from Corynebacterium diphtheriae was identified from T. pallidum . We describe here the characterization of TroR, a regulatory protein. Mobility-shift DNA binding and DNase I footprint assays indicated that purified TroR bound to a 22-nt region of dyad symmetry that overlaps the −10 region of the promoter of the tro operon, which contains the genes for a putative metal transport system, the glycolytic enzyme phosphoglycerate mutase, and TroR. Unlike other metal-dependent regulatory proteins like diphtheria toxin regulatory protein and the ferric ion uptake regulator, Fur, which can be activated by divalent metals such as Fe ²⁺ , Mn ²⁺ , Co ²⁺ , Ni ²⁺ , and Zn ²⁺ , TroR is activated only by Mn ²⁺ . The TroR-Mn ²⁺ complex binds its target sequence and blocks transcription of the tro PO/ lacZ fusion, suggesting that TroR acts as a metal-dependent repressor in vivo . In addition, TroR exists as a dimer in both its inactive (metal free) and active states as indicated by chemical crosslinking experiments. Based on these data, we propose that TroR represents a unique regulatory system for controlling gene expression in T. pallidum in response to Mn ²⁺ .