In Escherichia coli, proteins GidA and MnmE are involved in the addition of the carboxymethylaminomethyl (cmnm) group onto uridine 34 (U34) of tRNAs decoding two-family box triplets. However, their precise role in the modification reaction remains undetermined. Here, we show that GidA is an FAD-binding protein and that mutagenesis of the N-terminal dinucleotide-binding motif of GidA, impairs capability of this protein to bind FAD and modify tRNA, resulting in defective cell growth. Thus, GidA may catalyse an FAD-dependent reaction that is required for production of cmnmU34. We also show that GidA and MnmE have identical cell location and that both proteins physically interact. Gel filtration and native PAGE experiments indicate that GidA, like MnmE, dimerizes and that GidA and MnmE directly assemble in an α2β2 heterotetrameric complex. Interestingly, high-performance liquid chromatography (HPLC) analysis shows that identical levels of the same undermodified form of U34 are present in tRNA hydrolysates from loss-of-function gidA and mnmE mutants. Moreover, these mutants exhibit similar phenotypic traits. Altogether, these results do not support previous proposals that activity of MnmE precedes that of GidA; rather, our data suggest that MnmE and GidA form a functional complex in which both proteins are interdependent.
Role of the Carboxy Terminus of Escherichia coli FtsA in Self-Interaction and Cell Division
The role of the carboxy terminus of the Escherichia coli cell division protein FtsA in bacterial division has been studied by making a series of short sequential deletions spanning from residue 394 to 420. Deletions as short as 5 residues destroy the biological function of the protein. Residue W415 is essential for the localization of the protein into septal rings. Overexpression of the ftsA alleles harboring these deletions caused a coiled cell phenotype previously described for another carboxy-terminal mutation (Gayda et al., J. Bacteriol. 174:5362-5370, 1992), suggesting that an interaction of FtsA with itself might play a role in its function. The existence of such an interaction was demonstrated using the yeast two-hybrid system and a protein overlay assay. Even these short deletions are sufficient for impairing the interaction of the truncated FtsA forms with the wild-type protein in the yeast two-hybrid system. The existence of additional interactions between FtsA molecules, involving other domains, can be postulated from the interaction properties shown by the FtsA deletion mutant forms, because although unable to interact with the wild-type and with FtsA⌬1, they can interact with themselves and cross-interact with each other. The secondary structures of an extensive deletion, FtsA⌬27, and the wild-type protein are indistinguishable when analyzed by Fourier transform infrared spectroscopy, and moreover, FtsA⌬27 retains the ability to bind ATP. These results indicate that deletion of the carboxy-terminal 27 residues does not alter substantially the structure of the protein and suggest that the loss of biological function of the carboxy-terminal deletion mutants might be related to the modification of their interacting properties.FtsA is an essential cell division protein of Escherichia coli that is widely conserved in bacteria. Together with ftsZ, which codes for a GTPase analog of the eukaryotic tubulin, ftsA forms one of the most frequently conserved gene pairs among the cell division genes in the eubacteria. Based on sequence homology it has been proposed that FtsA belongs to the sugar kinase/hsp70/actin superfamily (4). This superfamily comprises several proteins with a common two-domain topology and the ability to bind and hydrolyze ATP. FtsA binds to columns of ATP-agarose and can be isolated from cells either as a phosphorylated or a nonphosphorylated form (29), but so far no other biochemical function has been described for this protein.FtsA is present both in the cytoplasm and in the cytoplasmic membrane (29), where it forms a structural part of the septum (32). It has been proposed that FtsA is a component of a membrane-associated complex (septator or divisome), which would include periplasmic, transmembrane, and cytoplasmic proteins acting coordinately to perform septation (27,35). Genetic analysis suggests that FtsA may interact, directly or indirectly, with other cell division proteins, such as FtsZ, PBP3, FtsQ, and FtsN (9,10,24,33,34). The FtsZ/FtsA ratio is important for cell division, an...
The GTPase Activity and C-terminal Cysteine of the Escherichia coli MnmE Protein Are Essential for Its tRNA Modifying Function
The Escherichia coli MnmE protein is a three-domain protein that exhibits a very high intrinsic GTPase activity and low affinity for GTP and GDP. The middle GTPase domain, when isolated, conserves the high intrinsic GTPase activity of the entire protein, and the C-terminal domain contains the only cysteine residue present in the molecule. MnmE is an evolutionarily conserved protein that, in E. coli, has been shown to control the modification of the uridine at the wobble position of certain tRNAs. Here we examine the biochemical and functional consequences of altering amino acid residues within conserved motifs of the GTPase and C-terminal domains of MnmE. Our results indicate that both domains are essential for the MnmE tRNA modifying function, which requires effective hydrolysis of GTP. Thus, it is shown for the first time that a confirmed defect in the GTP hydrolase activity of MnmE results in the lack of its tRNA modifying function. Moreover, the mutational analysis of the GTPase domain indicates that MnmE is closer to classical GTPases than to GTP-specific metabolic enzymes. Therefore, we propose that MnmE uses a conformational change associated with GTP hydrolysis to promote the tRNA modification reaction, in which the C-terminal Cys may function as a catalytic residue. We demonstrate that point mutations abolishing the tRNA modifying function of MnmE confer synthetic lethality, which stresses the importance of this function in the mRNA decoding process.The evolutionarily conserved MnmE (TrmE) protein of Escherichia coli is a GTPase that differs extensively from regulatory GTPases such as p21 (1). Thus, MnmE exhibits a very high intrinsic GTPase hydrolysis rate and low affinity for GTP and GDP, and it can form self-assemblies. MnmE has a molecular mass of 50 kDa and is organized as a multidomain protein (see Fig. 1) consisting of an ϳ220-amino acid N-terminal domain, probably required for self-assembly, a middle GTPase domain, of about 160 residues, and an ϳ75-amino acid C-terminal domain, which contains the only Cys residue present in the protein. Strikingly, the isolated GTPase domain roughly conserves the guanine nucleotide binding and GTPase activities of the intact MnmE molecule (1).Null mnmE mutants are defective in the biosynthesis of the hypermodified nucleoside 5-methylaminomethyl-2-thiouridine (mnm 5 s 2 U 34 ) 1 (2), which is found in the wobble position (position 34) of tRNAs that read codons ending with A or G, in the mixed codon family boxes, specifically tRNAs for lysine and glutamic acid (3). The mnmA gene product (6) carries out thiolation in the 2-position of the wobble uridine (U 34 ), whereas mnmE controls the first step of the modification in the 5Ј-position, but it is unclear how many steps precede the formation of cmnm 5 s 2 U 34 (2, 4). Several data support that a second gene, named gidA, trmF, or mnmG, is also involved in the cmnm 5 group addition and that the MnmE activity precedes the activity of GidA (2, 5). The mnmC gene product has two enzymatic activities that transform the cm...
FtsA plays an essential role in Escherichia coli cell division and is nearly ubiquitous in eubacteria. Several evidences postulated the ability of FtsA to interact with other septation proteins and with itself. To investigate these binding properties, we screened a phage-display library with FtsA. The isolated peptides defined a degenerate consensus sequence, which in turn displayed a striking similarity with residues 126-133 of FtsA itself. This result suggested that residues 126-133 were involved in homodimerization of FtsA. The hypothesis was supported by the analysis of correlated mutations, which identified a mutual relationship between a group of amino acids encompassing the ATP-binding site and a set of residues immediately downstream to amino acids 126-133. This information was used to assemble a model of a FtsA homodimer, whose accuracy was confirmed by probing multiple alternative docking solutions. Moreover, a prediction of residues responsible for protein-protein interaction validated the proposed model and confirmed once more the importance of residues 126-133 for homodimerization. To functionally characterize this region, we introduced a deletion in ftsA, where residues 126-133 were skipped. This mutant failed to complement conditional lethal alleles of ftsA, demonstrating that amino acids 126-133 play an essential role in E. coli.
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