Formation of Thiolated Nucleosides Present in tRNA from Salmonella enterica serovar Typhimurium Occurs in Two Principally Distinct Pathways

tRNA from Salmonella enterica serovar Typhimurium contains fivethiolated nucleosides, 2-thiocytidine (s²C), 4-thiouridine (s⁴U),5-methylaminomethyl-2-thiouridine (mnm⁵s²U), 5-carboxymethylaminomethyl-2-thiouridine(cmnm⁵s²U), and N-6-(4-hydroxyisopentenyl)-2-methylthioadenosine(ms²io⁶A). The levels of all of them are significantly reducedin cells with a mutated iscS gene, which encodes the cysteinedesulfurase IscS, a member of the ISC machinery that is responsiblefor [Fe-S] cluster formation in proteins. A mutant (iscU52)was isolated that carried an amino acid substitution (S107T)in the IscU protein, which functions as a major scaffold inthe formation of [Fe-S] clusters. In contrast to the iscS mutant,the iscU52 mutant showed reduced levels of only two of the thiolatednucleosides, ms²io⁶A (10-fold) and s²C (more than 2-fold). Deletionsof the iscU, hscA, or fdx genes from the isc operon lead toa similar tRNA thiolation pattern to that seen for the iscU52mutant. Unexpectedly, deletion of the iscA gene, coding foran alternative scaffold protein for the [Fe-S] clusters, showeda novel tRNA thiolation pattern, where the synthesis of onlyone thiolated nucleoside, ms²io⁶A, was decreased twofold. Basedon our results, we suggest two principal distinct routes forthiolation of tRNA: (i) a direct sulfur transfer from IscS tothe tRNA modifying enzymes ThiI and MnmA, which form s⁴U andthe s²U moiety of (c)mnm⁵s²U, respectively; and (ii) an involvementof [Fe-S] proteins (an unidentified enzyme in the synthesisof s²C and MiaB in the synthesis of ms²io⁶A) in the transferof sulfur to the tRNA.

INTRODUCTION

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Introduction

At present more than 80 different modified nucleoside derivativesof the four major nucleosides, adenosine (A), guanosine (G),uridine (U), and cytidine (C), have been characterized fromtRNAs from all three domains of life (54). One subgroup of thesemodifications is the thiolated nucleosides (4, 39), of which10 have been characterized so far and 5, 2-thiocytidine (s²C),4-thiouridine (s⁴U), 5-methylaminomethyl-2-thiouridine (mnm⁵s²U),5-carboxymethylaminomethyl-2-thiouridine (cmnm⁵s²U), and N-6-(4-hydroxyisopentenyl)-2-methylthioadenosine(ms²io⁶A), are present in tRNA from Salmonella enterica serovarTyphimurium (Fig. 1). In Escherichia coli the same thiolatednucleosides are present except for ms²io⁶A, which has been replacedby N-6-isopentenyl-2-methylthioadenosine (ms²i⁶A).

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FIG. 1. Structures and positions of thiolated nucleosides in tRNA. Abbreviations: s²C, 2-thiocytidine; s⁴U, 4-thiouridine; mnm⁵s²U, 5-methylaminomethyl-2-thiouridine; cmnm⁵s²U, 5-carboxymethylaminomethyl-2-thiouridine; ms²io⁶A, N-6-(4-hydroxyisopentenyl)-2-methylthioadenosine; ms²i⁶A, N-6-isopentenyl-2-methylthioadenosine. (c)mnm⁵s²U denotes both mnm⁵s²U and cmnm⁵s²U34; ms²i(o)⁶A denotes both ms²io⁶A and ms²i⁶A.

s⁴U, which is present in position 8 of a subpopulation of tRNAs,is the most prevalent thiolated nucleoside in tRNA from S. entericaand can act as a sensor for UV radiation, since UV exposureinduces the formation of a covalent bond between s⁴U8 and aC13 in some tRNAs (17, 63). This structural change results inpoor aminoacylation of tRNAs, thereby triggering the stringentresponse (52). The thio group of mnm⁵s²U34 is part of the recognitionelement for glutaminyl-tRNA synthetase (36, 60), and it alsorestricts the ability of the tRNA to read G-ending codons (2,68). Although lack of the ms² group of ms²io⁶A37 does not influencethe growth rate (15), it does influence the reading frame maintenance(66) and the speed with which some, but not all, ternary complexesof ms²io⁶A37-containing tRNAs enter the A-site (35). Formationof s²C32, which is present in only four tRNAs species from S.enterica, generates an altered anticodon loop structure (5)that may result in a lower translational efficiency (discussedin reference 9). Although a mutant lacking s²C32 exhibits wild-typegrowth, the A-site selection rate for some of the tRNAs normallycontaining s²C32 is dependent on this thiolated nucleoside (24a).Thus, all thiolated nucleosides present in tRNA of S. entericainfluence the activity of the tRNA in several ways and to differentdegrees.

Iron-sulfur clusters constitute one of the most ancient, ubiquitous,and functionally diverse classes of biological prosthetic groups(6-8, 19, 30). Proteins containing one or more [Fe-S] clustersare commonly called [Fe-S] proteins, and they represent a largeclass of structurally and functionally diverse proteins thatparticipate in many metabolic processes. The assembly of these[Fe-S] clusters into proteins is facilitated by a set of conservedproteins (IscS, IscU, IscA, HscA, HscB, and ferredoxin [Fdx]),which in many bacteria are encoded by genes organized in a singleoperon. In E. coli these genes constitute an operon of eightgenes transcribed in the order iscR-iscS-iscU-iscA-hscB-hscA-fdx-orf3(61) (Fig. 2). In front of this operon is a regulator gene,iscR, whose product regulates expression of the isc operon bysensing the [Fe-S] status of the cell (56). The desulfuraseIscS is involved in the assembly of most [Fe-S] clusters inthe cell by mobilizing the sulfur from the cysteine. The IscUfunctions as a scaffold for the [Fe-S] cluster assembly, andit is thought to accept sulfur from IscS and deliver it to thetarget apoprotein (58, 65). IscA is an alternative scaffoldto IscU for IscS-directed [Fe-S] cluster assembly, and it interactswith Fdx, also encoded by the isc operon (31, 44). The HscAchaperone interacts specifically with IscU by recognizing aspecific amino acid sequence (24).

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FIG. 2. Organization of the isc operon: iscR codes for the negative regulator of the operon, iscS codes for pyridoxal-phosphate-dependent cysteine desulfurase, iscU codes for the scaffold protein for [Fe-S] cluster assembly, iscA codes for the alternative scaffold protein for [Fe-S] cluster assembly, hscB codes for a J-type molecular cochaperone, hscA codes for a Hsp70-type molecular chaperone, and fdx codes for [2Fe-2S] Fdx.

Synthesis of the thiolated nucleosides is a complex and multi-stepprocess (Fig. 3). For many years, our knowledge about the thiolationstep was limited to knowing that the sulfur originates fromcysteine (3). We know now that IscS is required for the synthesisof s⁴U (26, 46) and, further, that IscS is involved in the synthesisof all thiolated nucleosides in tRNA of S. enterica (43) andE. coli (32). In the synthesis of s⁴U, the sulfur is first transferredfrom cysteine to IscS, thereby forming a persulfide at Cys328in the active site of IscS. Then the persulfide sulfur fromIscS is transferred to a cysteine in ThiI, which in turn transfersthe sulfur to a uridine at position 8 of tRNA (26, 41, 46).Alternatively, the sulfur from ThiI may be transferred to anotherprotein, ThiS, which transfers the sulfur to the thiazole moietyin the formation of thiamine (62, 67). Thus, the syntheses ofthiamine and s⁴U are metabolically linked. The persulfide sulfurof IscS may also be transferred to another acceptor protein,MnmA, which in turn transfers the sulfur to a uridine in thewobble position of a subset of tRNAs forming the s²U moietyof mnm⁵s²U (27). The product of the miaB gene participates inthe methylthiolation of A37 in a subset of tRNAs that read codonsstarting with U (15, 16). MiaB contains an iron-sulfur complex(49) and is a member of the Radical SAM protein superfamily,which utilizes the combination of a labile iron-sulfur clusterand S-adenosylmethionine (SAM) to initiate radical catalysis(10, 18, 59). The synthesis of s²C is poorly understood; however,it is known that the product encoded by the ttcA gene is requiredfor its synthesis (24a). In conclusion, these results suggestthat the determinants of thiolation of U at positions 2 and4 are similar whereas the methylthiolation reaction in the synthesisof ms²io⁶A is different. Interestingly, studies of an iscS deletionmutant revealed that the synthesis of s²C and ms²io⁶A couldstill occur at lower rates, suggesting the existence of an alternativepathway for the mobilization of sulfur, independent of IscS(32, 43).

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FIG. 3. Biosynthetic pathways of the formation of thiolated nucleosides. U8 is thiolated at position 4 by ThiI, which receives the sulfur directly from IscS (26, 41, 46). U34 undergoes thiolation at position 2 catalyzed by MnmA, which acquires sulfur from IscS (27). The first step in the formation of the mnm⁵ side chain is the formation of cmnm⁵ group by MnmE and GidA. The cmnm⁵ group is then rearranged in two steps catalyzed by MnmC to synthesize the mnm⁵ side chain (23). The thiolation step and the formation of the mnm⁵ side chain occur independently, because thiolation may precede or follow the synthesis of the side chain at position 5. In the thiolation of C32 at position 2, the enzyme TtcA is involved (24a). A37 receives isopentenyl group at position 6 from isopentenyl pyrophosphate (IPP) in the reaction catalyzed by MiaA (34, 40, 53). In the later methylthiolation step at position 2 of adenosine, MiaB is involved (15, 16, 49). The MiaE protein is required for the hydroxylation of the i⁶ group (48). *, see the text for details.

This paper addresses the role of IscU, IscA, HscA, and Fdx inthe thiolation of tRNA. We show that in contrast to the roleof IscS, which is involved in the synthesis of all thiolatednucleosides, IscU, HscA, and Fdx influence only the synthesisof s²C and ms²io⁶A whereas IscA influences only the synthesisof ms²io⁶A. Based on our results, we suggest that the thiolationof tRNA occurs in two principally distinct ways—one leadingto s⁴U and (c)mnm⁵s²U formation, and the other leading to s²Cand ms²io⁶A formation.

MATERIALS AND METHODS

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Materials and Methods

Bacteria and growth conditions. The bacterial strains used were derivatives of S. enterica (Table1). Cultures were grown in NAA complex medium (0.8% Difco nutrientbroth; Difco Laboratories, Detroit, Mich.) supplemented withthe aromatic amino acids, aromatic vitamins, and adenine atconcentrations as described previously (12). As the definedrich liquid medium, morpholinepropanesulfonic acid (MOPS) medium,discribed by Neidhart et al. (42), was used. As the rich solidmedium, TYS agar (10 g of Trypticase peptone, 5 g of yeast extract,5 g of NaCl, and 15 g of agar per liter) was used.

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TABLE 1. Salmonella strains used in this study

Genetic procedures. Transduction with phage P22 HT105/1 (int-201) (55) was performedas described previously (12). DNA sequencing was performed oneither chromosomal DNA or PCR products as described in the manualfor the Applied Biosystems ABI Prism cycle-sequencing BigDyeReady Reaction kit. The deletion mutants used in this studywere constructed by first inserting in the gene of interesta PCR fragment coding for antibiotic resistance, which laterwas eliminated from the chromosome leaving an in-frame "scar"of an 84-nucleotide insertion as described previously (11).The scar in the ${Delta}$ iscU53 mutant is inserted between the seventhand the seventh-to-last nucleotide, the scar in the ${Delta}$ hscA51 mutantis inserted between the fifth and the fifteenth-to-last nucleotide,the scar in the ${Delta}$ iscA54 mutant is inserted between the sixthand the fifth-to-last nucleotide, and the scar in the ${Delta}$ fdx51mutant is inserted between the sixth and the sixth-to-last nucleotideof the respective gene. All mutations were confirmed by DNAsequencing.

Analysis of modified nucleosides in tRNA. Bacterial strains were grown in NAA medium at 37°C to about4 x 10⁸ to 6 x 10⁸ cells/ml (100 to 150 Klett units). The cellswere lysed, and total RNA was prepared (13), dissolved in R200buffer (10 mM Tris-H₃PO₄ [pH 6.3], 15% ethanol, 200 mM KCl),and applied to a Nucleobond column equilibrated with the samebuffer. tRNA was eluted with the same buffer, except that theKCl concentration was raised to 600 mM. The tRNA was precipitatedwith 2.5 volumes of cold ethanol containing 1% of potassiumacetate, washed twice with 70% ethanol, and dried. It was thendissolved in water, and a 100-µg sample was degraded tonucleosides with nuclease P1 followed by treatment with bacterialalkaline phosphatase (22). The resulting hydrolysate was analyzedby high-performance liquid chromatography (HPLC) (21). The chromatogramswere scanned at specific wavelengths to optimize the quantificationof each of the four thiolated nucleosides. The levels of thevarious thiolated nucleosides at the specific wavelengths werenormalized to that of t⁶A at 254 nm. The values for ms²i(o)⁶Arepresent those for ms²io⁶A and ms²i⁶A taken together; similarly,the values for (c)mnm⁵s²U represent those for mnm⁵s²U and cmnm⁵s²Utaken together.

RESULTS

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Results

Strain GT2919 has a reduced growth rate and is deficient in both s²C and ms²io⁶A. Strains with a + 1 frameshift mutation, hisD3749, are dependenton added histidine for growth. A defective

(encoded by the proL gene) allows

(encoded by the proM gene) to suppress the hisD3749 mutation, resulting in theHis⁺ phenotype (51). By using localized mutagenesis in the proLregion, strain GT2919 (proL207 hisD3749) was isolated (50),which, besides being His⁺, had a reduced growth rate and a changedtRNA modification pattern. tRNA from strain GT2919 had reducedlevels of two modified nucleosides: s²C and ms²io⁶A (Fig. 4).Note, however, that those two modified nucleosides are not presentin

. Genetic studies revealed that the proL207mutation, which caused the His⁺ phenotype, was linked neitherto the decreased levels of s²C and ms²io⁶A nor to the reducedgrowth rate. A new mutation causing the last two phenotypeswas temporarily called miaC1, since it was the third gene identifiedto influence the synthesis of ms²io⁶A.

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FIG. 4. HPLC chromatograms of tRNA hydrolysates from wild-type (A) and iscU52 mutant (B) strains. The nucleosides were monitored at 295 nm to maximize the detection of all thiolated nucleosides. mnm⁵s²U, s⁴U, ms²io⁶A, and i⁶A were identified by comparing UV spectra with published spectra (21); for s²C, the molecular weight of the protonated form was determined by mass spectrometry (24a). AU, absorbance units.

The miaC1 mutation is located within the isc operon. To localize the miaC1 mutation, a random pool of Tn10dTc insertionsin the wild-type strain LT2 was introduced into the slow-growingGT3590 mutant (miaC1) and fast-growing colonies on rich mediumplates at 30°C were monitored. The Tn10dTc insertion fromone of the fast-growing transductants was found to be 28% linkedto the miaC1 mutation, as demonstrated by backcrosses to strainGT3590 (data not shown). The miaC1 mutation was transferredto the wild-type strain LT2 by P22 transduction. tRNA was preparedfrom 10 slow-growing and 10 fast-growing transductants for HPLCanalysis of their modification patterns. All slow-growing transductantshad reduced levels of s²C and ms²io⁶A in their tRNAs, whereasthe fast-growing ones showed the wild-type tRNA modificationpattern (Fig. 4; for quantifications, see Fig. 5). One fast-and one slow-growing transductant were saved as congenic strainsGT4767 (miaC⁺) and GT4768 (miaC1).

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FIG. 5. Mutations in the iscU, hscA, and fdx genes affect the levels of s²C and ms²io⁶A, whereas mutation in iscA reduces only the level of ms²io⁶A. *, The iscU and iscA mutations were complemented by a plasmid harboring the iscU and iscA genes in the high-copy-number pGEM vector (data not shown).

The chromosomal region on each side of the Tn10dTc transposonin strain GT4768 was sequenced with primers specific for theends of the Tn10dTc transposon. The results showed that Tn10dTcwas inserted into the sseA gene. The miaC1 mutation causingslow growth and a deficiency in s²C and ms²io⁶A in the tRNAwas localized to the region between the sseA and STM2545 genesby transductional mapping using strains carrying different markerslocated in the vicinity of the sseA gene (glyA-540::Tn10dTc,zee-2526::MudSacI, and STM2545::Tn10dTc) (data not shown). Thecotransduction frequency (28%) between the miaC1 mutation andsseA2527::Tn10dTc, together with the mapping data, suggestedthat the mutation was within the isc operon.

The miaC1 mutation is located in the iscU gene. To locate the miaC1 mutation more precisely, we sequenced theentire isc operon in strain GT4768. The only mutation that wefound was in the iscU gene, resulting in a substitution of Thrfor Ser at position 107 of the IscU protein. Therefore, we renamedmiaC1 to iscU52. A plasmid that contains iscU and iscA genescomplemented the slow growth and modification deficiency ofthe iscU52 mutant GT4768 (see the discussion of Fig. 5). Theseresults demonstrate that the slow growth and reduced levelsof s²C and ms²io⁶A in tRNA are caused by the iscU52 mutation.

To verify the role of IscU in the formation of the two modifiednucleosides, s²C and ms²io⁶A, in tRNA, we deleted the iscU gene.The ${Delta}$ iscU53 mutation had a similar effect on the modificationof tRNA to that of the iscU52 point mutation: it caused a 60%reduction in the level of s²C and more than a 10-fold reductionin the level of ms²io⁶A (Fig. 5).

Lack of the HscA chaperone results in s²C and ms²io⁶A deficiency in tRNA. Three conserved cysteine residues at positions 37, 63, and 106are all essential for the function of IscU in vivo by providinga scaffold for the sequential assembly of [Fe-S] clusters (1,28, 58, 69). At residues 99 and 103 of IscU, the motif LPPVKis found, which is required for the interaction with the molecularchaperone HscA (24). Sequence alignment demonstrated that thismotif is invariant in all of the IscU homologs identified todate. The amino acid substitution S107T in IscU52 is only 3amino acids away from this conserved region (Fig. 6) and mightprevent the IscU-HscA interaction by altering the structureof the HscA recognition domain. This hypothesis suggests a roleof HscA in the modification of tRNA. Therefore, a strain (GT6582)with a nonpolar deletion of the hscA gene was constructed. Evidently,tRNA from the ${Delta}$ hscA51 mutant showed a similar decrease in thelevels of s²C and ms²io⁶A to that of tRNA from the ${Delta}$ iscU53 mutant(Fig. 5), consistent with the view that HscA and IscU interactduring the synthesis of these two thiolated nucleosides.

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FIG. 6. Schematic presentation of the IscU protein with conserved cysteines indicated. C63 forms a disulfide bridge with C328 of IscS (28). In the expanded region, the HscA binding site, LPPVK (24), and S107, which is altered to T107 by the iscU52 mutation, are depicted.

IscA influences only the level of ms²io⁶A. Since IscA and IscU have a similar function in [Fe-S] clusterassembly (31, 44), we decided to investigate the involvementof IscA in tRNA thiolation. Strain DM5420 (iscA2::MudJ) containsa MudJ transposon insertion disrupting the iscA gene and mostprobably decreasing the expression of the downstream genes hscB,hscA, and fdx due to polarity effects (57). Analysis of themodification pattern of the tRNA from the strain DM5420 showedthat the levels of s²C and ms²io⁶A were both decreased to levelssimilar to those reached in the hscA mutant (Table 2), suggestingthat the effect we observed in DM5420 strain might be causedby the decrease in the synthesis of HscA. To establish whichof the two proteins, IscA or HscA, is required for the synthesisof these two thiolated nucleosides, a strain (GT6593) with anonpolar deletion of the iscA gene was constructed. Unexpectedly,analysis of the total tRNA purified from that strain revealedthat the presence of IscA is critical only for the synthesisof ms²io⁶A, since its level was decreased twofold (Fig. 5).The levels of the other three thiolated nucleosides were similar(s²C) or increased [(c)mnm⁵s²U and s⁴U] compared to the levelsobserved in the wild-type strain.

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TABLE 2. Levels of thiolated nucleosides in tRNA from the different mutants of iscA, and iscU grown in NAA rich medium

Increased levels of the IscA cannot substitute for the function of the IscU. Since both IscU and IscA can serve as scaffolds for [Fe-S] assembly,we tested whether IscA provided at higher levels could substitutefor the activity of IscU. Therefore, a plasmid (piscA1) carryingthe iscA⁺ gene (57) was introduced into the strains GT6594 ( ${Delta}$ iscU53)and GT 6593 ( ${Delta}$ iscA54). Analysis of the tRNA modification patternrevealed that the low levels of ms²io⁶A in the ${Delta}$ iscA54 mutantwere restored to wild-type levels when IscA was provided onthe plasmid (Table 2). However, tRNA originating from the ${Delta}$ iscU53/piscA1strain still had the thiolation pattern characteristic of the ${Delta}$ iscU53 mutant. We conclude that IscA cannot substitute for IscUin the synthesis of s²C or of ms²io⁶A.

Fdx influences the synthesis of two thiolated nucleosides, s²C and ms²io⁶A. IscA was shown to form a complex with and transfer iron andsulfide to Fdx (Fdx is another member of the isc operon) toform [2Fe-2S] holoferredoxin (44). We tested if a lack of Fdxwould give a similar phenotype to that resulting from a lackof IscA. A ${Delta}$ fdx51 mutant (strain GT6645) was constructed, andits tRNA thiolation pattern was analyzed. In contrast to the ${Delta}$ iscA54 tRNA, which was affected only in the levels of ms²io⁶A,the tRNA from the ${Delta}$ fdx51 mutant had reduced levels of two thiolatednucleosides, s²C (35% of the wild-type level remaining) andms²io⁶A (11% of the wild-type level remaining) (Fig. 5), similarto the reduction observed in the ${Delta}$ iscU53 and ${Delta}$ hscA51 strains.

Growth characteristics of the mutants defective in the isc operon. The iscU52 mutant forms small colonies on rich-medium agar plates.Therefore, the colony sizes of all the mutants used in thisstudy were determined by measuring the diameters of the coloniesgrown on rich TYS agar plates at 30°C (the reduction ingrowth was more pronounced at 30°C than at 37°C) for24 h. A general reduction in colony sizes to 64 to 77% of thesize of the wild-type colonies was observed (Table 3).

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TABLE 3. Growth characteristics of different mutants mutated in the isc operon

The steady-state growth rates in a defined rich medium at 37°Cwere also reduced in the various mutants compared to that ofthe wild type (Table 3). In the iscU52 and ${Delta}$ fdx51 mutants, thereduction was 30%, and in the ${Delta}$ iscU53, ${Delta}$ iscA54, and ${Delta}$ hscA51 mutants,it was somewhat lower (10 to 20%). We noticed that the iscU52, ${Delta}$ iscU53, ${Delta}$ hscA51, and ${Delta}$ fdx51 mutants were unable to form densecultures, since they never grew to to a cell density of morethat 2.4 to 2.7 optical density at 420 nm (OD₄₂₀) units, whereasthe wild-type strain reached a cell density of 5.5 to 5.7 OD₄₂₀units. The ${Delta}$ iscA54 mutant had an intermediate final cell densityof 3.8 to 4.0 OD₄₂₀ units.

DISCUSSION

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Discussion

In this study we showed that different [Fe-S] proteins encodedin the isc operon differentially affect the synthesis of thefive thiolated nucleosides present in tRNA of S. enterica. Whereasmutation in the iscS gene reduces the levels of all the thiolatednucleosides in tRNA [s²C, s⁴C, (c)mnm⁵s²U, and ms²io⁶A] (32,43), mutation in the iscU, hscA, or fdx gene reduced the synthesisof only two of them, s²C and ms²io⁶A. Mutation in the iscA genereduced the level of only one thiolated nucleoside, ms²io⁶A(Fig. 5).

In the synthesis of s⁴U and the s²U moiety of (c)mnm⁵s²U, thesulfur is delivered from IscS to ThiI and MnmA, respectively;they, in turn, transfer it to tRNA (26, 27, 33, 41, 46). ThiIand MnmA share a weak sequence homology and carry conservedcysteine residues, but neither of them is an [Fe-S] protein.On the other hand, MiaB, which is involved in the synthesisof ms²io⁶A, possesses an oxygen-sensitive [Fe-S] cluster, whosepresence is essential for successful methylthiolation of theadenosine of tRNA in vivo (49). Synthesis of s²C is dependenton the TtcA protein (24a), and its amino acid sequence doesnot reveal any obvious [Fe-S] cluster motif. However, it containsseven Cys residues, of which four are clustered in two conservedC-X₁-X₂-C motifs that could have the potential for [Fe-S] clusterformation.

The lack of IscU, HscA, or Fdx reduces the activities of [Fe-S]enzymes 5- to 10-fold in E. coli, most probably due to the absenceof [Fe-S] clusters in these enzymes (64). Assuming that thehomologous proteins encoded by the isc operon of S. entericahave similar effects, we expected that the activity of the [Fe-S]cluster protein MiaB should be reduced in the ${Delta}$ iscU53, ${Delta}$ hscA51,and ${Delta}$ fdx51 mutants. Indeed, this was observed, since the levelof ms²io⁶A in tRNA was reduced 10-fold compared to the levelin the wild type (Fig. 5). The levels of s²C were reduced two-to threefold, further suggesting that TtcA contains an [Fe-S]cluster of its own or that there are other [Fe-S] cluster-containingproteins upstream or/and downstream of TtcA in the s²C syntheticpathway. However, the activity of those unknown [Fe-S] proteinsis not absolutely required, since low levels of thiolation arestill produced in the various isc operon mutants. It is alsopossible that small amounts of the correct clusters originatefrom alternative [Fe-S] cluster-forming machinery, such as SufABCDSE.

Based on these results, we suggest that there are two principaldistinct routes for the biosynthesis of the thiolated nucleosides(Fig. 7). Following the action of IscS, which affects the formationof all thiolated nucleosides in tRNA, the synthesis divergesinto (i) the syntheses of s⁴U and (c)mnm⁵s²U, where the sulfuris directly transferred from IscS to the tRNA-modifying enzymesand where apparently no [Fe-S] protein participates, and (ii)the biosynthetic pathways leading to the synthesis of s²C andms²io⁶A, which need, besides IscS, other constituents of theISC machinery since they comprise proteins containing [Fe-S]clusters. Also in support of the presence of two separate pathwaysis the recent observation that synthesis of s⁴U and s²U is completelydependent on IscS as the sulfur donor, whereas an inefficientsynthesis of s²C and ms²io⁶A occurs in an IscS-independent way(32, 43).

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FIG. 7. Working model for sulfur trafficking in tRNA thiolation. Solid lines represent experimentally verified pathways, and dashed lines represent hypothetical productive interactions between the proteins. See the text for further detail.

IscU and IscA are both scaffold proteins, presumably with similarfunctions in the [Fe-S] cluster assembly (1, 44). Since mostbacteria seem to have both these scaffold proteins, their functionmight be not completely overlapping. It is generally thoughtthat IscU is the key player in the assembly process. This viewis supported by the fact that deletion of the two IscU homologuesin yeast is lethal whereas deletion of both IscA homologs isnot (20, 25, 29, 47). We therefore expected that lack of IscAwould result in no detectable phenotype if IscU was epistaticto IscA and the target apoproteins were the same for the twoscaffold proteins. Alternatively, if these two scaffold proteinshad an additive effect, we would expect the lack of IscA tohave an effect on the synthesis of s²C and ms²io⁶A, since lackof IscU reduced the synthesis of both these nucleosides. Surprisingly,only the synthesis of ms²io⁶A was affected by the deletion ofthe iscA gene (Fig. 5). This result could indicate that, foroptimal activity, MiaB requires the assistance of the scaffoldprotein IscA or, more probably, could reflect the possible roleof IscA in the restoration of the [Fe-S] cluster in MiaB. MiaBhas an oxygen-labile cluster, which is a common feature of proteinsbelonging to the Radical SAM family. Such clusters are moresensitive to oxidative damage and require more efficient repair.This could explain, why the absence of IscA affected only thesynthesis of ms²io⁶A, but not that of s²C, provided that theprotein(s) working in the latter pathway has a more stabile[Fe-S] cluster.

Since IscA and IscU have similar functions in the [Fe-S] clusterassembly, it can be assumed that overproduction of one of themmay suppress the lack of the other. However, introduction ofa plasmid encoding IscA did not suppress the phenotype of the ${Delta}$ iscU53 mutant, since it still had decreased levels of s²C andms²io⁶A (Table 2). Hence, IscA cannot substitute for IscU inthe assembly of [Fe-S] clusters in MiaB or in the protein(s)participating in the synthesis of s²C.

Biotin synthase (BioB) is an [Fe-S] enzyme and catalyzes thelast step of biotin biosynthesis (38). BioB and MiaB have functionalsimilarity since they both catalyze a C-H to C-S bond conversionand are members of the same family of Radical SAM enzymes (37,59). Recently, it was shown that [Fe-S] cluster assembly occurredin BioB in vitro when the transient cluster was provided byIscA (45). However, our experiments on the suppression of the ${Delta}$ iscU53 mutant by the piscA1 plasmid could not confirm clusterassembly in MiaB by IscA when we tested MiaB for tRNA-modifyingactivity (Table 2). This could be due to differences in theconditions as we monitored the processes inside the cell, whichis difficult to reproduce in the experiments done in vitro,or could be due to the fact that MiaB, in contrast to BioB,needs a cluster provided exclusively by IscU.

While all the mutants analyzed had a decreased synthesis ofs²C and ms²io⁶A, the levels of the other two thiolated nucleosides,s⁴U and (c)mnm⁵s²U, were slightly increased (17 to 29% comparedto the wild-type levels [Fig. 5]). It is known that the transcriptionalrepressor of the isc operon, IscR, needs a functional [Fe-S]cluster for its activity. In iscS and hscA mutants (56) as wellas in iscU and fdx mutants (Fig. 5; Table 3), the assembly of[Fe-S] clusters is significantly reduced and therefore IscRloses its repressing abilities, resulting in increased expressionof the isc operon. Since IscS is directly transferring the sulfurto tRNA-modifying enzymes, the increased levels of s⁴U and (c)mnm⁵s²Uin tRNA may reflect an increased level of IscS. Such an explanationwould require a slight undermodification of the tRNA under thegrowth conditions used; i.e., some tRNAs would not have a molarcontent of s⁴U and (c)mnm⁵s²U. This may be true, since thiolationof tRNA varies with the growth rate (14). The observed increasedlevels of s⁴U and (c)mnm⁵s²U in various mutants (Fig. 5) suggestthat deficiency in any of the [Fe-S] assembly proteins, IscU,IscA, HscA, or Fdx, results in more efficient transfer of sulfurto uridines of tRNA. The very large increase in the level of(c)mnm⁵s²U in the ${Delta}$ iscA54 mutant is more difficult to reconcilewith such a suggestion, since it would require that about 39%of the possible (c)mnm⁵s²U sites in the tRNA not be thiolatedwhen cells are growing logarithmically in a rich medium.

Observed defects in the growth rate of strains harboring variousmutations in the isc operon can be due either to a reductionin the activities of some [Fe-S] enzymes critical for cell growthor to the lack of thiolated nucleosides in the tRNA. Since lackof s²C (24a) and lack of the methylthio group of ms²io⁶A (15)in the tRNA does not influence the growth rate, we suggest thatthe reduced growth rate in ${Delta}$ iscU53, ${Delta}$ hscA51, or ${Delta}$ fdx51 mutantsis caused by the deficiencies of [Fe-S] clusters in a protein(s)critical to obtain a maximal growth rate but not specificallyfor the synthesis of s²C and ms²io⁶A.

ACKNOWLEDGMENTS

This work was supported by grants from the Swedish Cancer Foundation(project 680) and Swedish Science Research council (projectBU-2930).

We are grateful for the generous gift of strain DM5420 and plasmidpiscA1 from Diana Downs, University of Wisconsin, Madison. Wethank Kerstin Jacobsson for skillful analysis of modified nucleosidesby HPLC and Mike Pollard, Tord Hagervall, Mikael Wikström,and Arunas Leipus for critical reading of the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular Biology, Umeå University, S-90187 Umeå, Sweden. Phone: 46 90 7856756. Fax: 46 90 772630. E-mail: glenn.bjork{at}molbiol.umu.se.

Present address: Telecommunication System Inc., Annapolis, MD21401.

REFERENCES

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