Abstract
The Tat (twin-arginine translocation) system of Escherichia coli serves to translocate folded proteins across the cytoplasmic membrane. The reasons established so far for the Tat dependence are cytoplasmic cofactor assembly and/or heterodimerization of the respective proteins. We were interested in the reasons for the Tat dependence of novel Tat substrates and focused on two uncharacterized proteins, YcdO and YcdB. Both proteins contain predicted Tat signal sequences. However, we found that only YcdB was indeed Tat-dependently translocated, whereas YcdO was equally well translocated in a Tat-deficient strain. YcdB is a dimeric protein and contains a heme cofactor that was identified to be a high-spin Fe(III)-protoporphyrin IX complex. In contrast to all other periplasmic hemoproteins analyzed so far, heme was assembled into YcdB in the cytoplasm, suggesting that heme assembly could take place prior to translocation. The function of YcdB in the periplasm may be related to a detoxification reaction under specific conditions because YcdB had peroxidase activity at acidic pH, which coincides well with the known acid-induced expression of the gene. The data demonstrate the existence of a class of heme-containing Tat substrates, the first member of which is YcdB.
Highlights
Periplasmic and more abundant at acidic pH [6]
YcdB Is a Tat Substrate, whereas YcdO Is Not—YcdB from E. coli is distantly related to the dye-decolorizing peroxidase (DyP)2 identified in the fungus G. candidum [16, 17]
YcdB Is the First Member of a New Class of Tat Substrates—This study was initiated to reveal the translocation mode and structural characteristics of two postulated protein substrates of the Tat system, YcdB and YcdO. Of these two proteins, only YcdB is a Tat substrate in E. coli, and this protein turned out to be the first example of a Tat-dependently translocated hemoprotein
Summary
Periplasmic and more abundant at acidic pH [6]. Studies on global gene regulation have shown that the expression of the whole ycdNOB gene cluster is induced in response to acidic conditions [7]. We aimed to analyze biochemically the uncharacterized putative E. coli Tat substrates YcdB and YcdO. While YcdO turned out not to be a Tat substrate, we found that YcdB is translocated by the Tat system. YcdB contains a noncovalent heme cofactor, and this cofactor is assembled in the cytoplasm. The data demonstrate that YcdB is the first member of a new class of hemecontaining Tat substrates with homologs in many bacterial species
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