Abstract
Controlling iron homeostasis is crucial for all aerobically grown living cells that are exposed to oxidative damage by reactive oxygen species (ROS), as free iron increases the production of ROS. Methionine sulfoxide reductases (Msr) are key enzymes in repairing ROS-mediated damage to proteins, as they reduce oxidized methionine (MetSO) residues to methionine. E. coli synthesizes two Msr, A and B, which exhibit substrate diastereospecificity. The bacterial iron-responsive small RNA (sRNA) RyhB controls iron metabolism by modulating intracellular iron usage. We show in this paper that RyhB is a direct regulator of the msrB gene that encodes the MsrB enzyme. RyhB down-regulates msrB transcripts along with Hfq and RNaseE proteins since mutations in the ryhB, fur, hfq, or RNaseE-encoded genes resulted in iron-insensitive expression of msrB. Our results show that RyhB binds to two sequences within the short 5′UTR of msrB mRNA as identified by reverse transcriptase and RNase and lead (II) protection assays. Toeprinting analysis shows that RyhB pairing to msrB mRNA prevents efficient ribosome binding and thereby inhibits translation initiation. In vivo site directed-mutagenesis experiments in the msrB 5′UTR region indicate that both RyhB-pairing sites are required to decrease msrB expression. Thus, this study suggests a novel mechanism of translational regulation where a same sRNA can basepair to two different locations within the same mRNA species. In contrast, expression of msrA is not influenced by changes in iron levels.
Highlights
Reactive oxygen species (ROS) can damage most macromolecules, proteins, nucleic acids and lipids [1]
To assess whether the decrease in expression of the translational reporter observed with the 2,29dip was due to a decrease in both msrB mRNA and protein levels, we measured the amount of msrB mRNA and MsrB protein within the cell by Northern and Western blot analyses, respectively
Introducing a fur mutation in JB44 (JB46) abolished 2,29dip repression, yielding a down constitutive iron-independent phenotype (Table 3). These results show the expression of the msrB gene to be regulated by the Ferric uptake regulator (Fur)/RyhB cascade such that msrB expression decreases under iron starvation
Summary
Reactive oxygen species (ROS) can damage most macromolecules, proteins, nucleic acids and lipids [1]. Within proteins, sulfurcontaining amino acids, cysteine and methionine (Met) exhibit high sensitivity [2]. Methionine oxidation yields methionine sulfoxide (Met-SO) and eventually methionine sulfone. The oxidation of Met to Met-SO can be reversed by the action of methionine sulfoxide reductases (Msr) [6,7,8,9,10]. Such an ability to reverse methionine oxidation has led credence to the idea that the surface-exposed Met residues act as scavengers for ROS and that reduction by Msr enables proteins to recover activity [11]
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