Incorporation of Fe-S into proteins requires Fe-S cluster assembl

Incorporation of Fe-S into proteins requires Fe-S cluster assembly systems, which were named Suf and Isc in E. coli. Our data showed that SufA, SufB, SufC and SufS, four of the six subunits

of the Suf complex, were more abundant under iron starvation conditions. Regulation of the Y. pestis suf operon by Fur and a functional RAD001 clinical trial Fur-binding site were reported previously [20]. The cysteine desulfurase subunits of the Suf and Isc systems (SufS and CsdA, respectively) were quantitatively changed in opposite directions (-Fe vs. +Fe), suggesting that Suf functionally replaces Isc at the onset of iron starvation in Y. pestis. Mobilization of sulfur from cysteine appears to be catalyzed by SufS in E. coli [71]. The increased abundance of TauD, an find more enzyme that mobilizes sulfite from taurine, in iron-depleted Y. pestis cells was intriguing. TauD is a dioxygenase, harbors a Fe2+ cofactor and was reported to be induced under sulfate starvation conditions in E. coli [72]. We speculate that TauD plays an accessory role in sulphur mobilization for Fe-S cluster assembly via the Suf pathway. www.selleckchem.com/products/a-1155463.html Furthermore, the Y. pestis ortholog of a recently discovered Fe-S cluster protein ErpA was also increased under iron-limiting conditions. Since ErpA was proposed to transfer Fe-S clusters to apo-enzymes [56], we hypothesize that Y. pestis ErpA may perform such activities cooperatively with the Suf system. Transcriptional

data on erpA and tauD expression changes for -Fe vs. +Fe growth conditions are not available. Mammalian hosts starve Y. pestis of iron and, therefore, the Suf complex constitutes a good target for inhibitory drug design. Enzymes with Fe-S clusters in their catalytic cores, many of them in the TCA cycle, are also displayed in Figure 5. Although in different Vasopressin Receptor ratios, subunits of such enzyme complexes (e.g. FumA, SdhA, FrdA and CysJ) were invariably decreased in abundance in iron-starved Y. pestis cells. Most of these quantitative decreases appear to be unrelated to population density differences, because they were not observed in cells cultured to stationary vs. exponential phase in iron-replete PMH2 medium(Pieper, R., unpublished data).

A decreased pyruvate metabolism rate should be the consequence of the loss of Fe-S cluster enzyme activities in the TCA cycle and may be followed by reduced production of ATP and NADPH reducing equivalents in the electron transport chain. Furthermore, a decreased turnover of citrate may lead to its accumulation in the cytoplasm, which could chelate iron and exacerbate iron starvation [30]. A highly interesting observation was the dramatic abundance and activity increase of PoxB in iron-starved Y. pestis cells, both at 26°C and 37°C. PoxB activity increases were independent of Y. pestis cell densities during growth in chemically defined media. poxB expression was reported to be moderately enhanced in Y. pestis cells grown in human plasma vs.

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