Báo cáo khoa học: Properties and significance of apoFNR as a second form of air-inactivated [4Fe-4S]ÆFNR of Escherichia coli pot

Formation of apoFNR and the redox state of the cysteinyl residues were determined in vitro by alkylation.. Recently it has been shown that various forms of apoFNR exist in vitro which di

of air-inactivated [4Fe-4S]ÆFNR of Escherichia coli

Stephanie Achebach1,*, Thorsten Selmer2,* and Gottfried Unden1

1 Institut fu¨r Mikrobiologie und Weinforschung, Johannes Gutenberg-Universita¨t Mainz, Germany

2 Laboratorium fu¨r Mikrobiologie, Philipps-Universita¨t, Marburg, Germany

Fumarate nitrate reductase regulator (FNR) is a

cyto-plasmic O2 sensor and regulator present in Escherichia

coli and other bacteria [1–7] The protein is required

for transcriptional regulation of many genes of

faculta-tive anaerobic metabolism in response to O2

availabil-ity [8] and responds to O2 concentrations in the

medium as low as 1–5 mbar O2 (about 1–5 lm O2)

[7,9,10] The rate of O2 diffusion into the bacteria is

high compared with the low rates of O2 consumption

at the cytoplasmic membrane or within cytoplasm

[3,7,9] Therefore O2 tension within the bacterial

cyto-plasm appears to be similar to that in the external

medium under oxic and microoxic conditions Active

FNR containing a [4Fe-4S] cluster, is found

under anoxic conditions In the presence of O2,

[4Fe-4S]ÆFNR is converted to [2Fe-2S]ÆFNR resulting

in monomerization and inactivation of FNR as a gene regulator The [4Fe-4S]⁄ [2Fe-2S] conversion is respon-sible for the anaerobic⁄ aerobic switch of FNR and has been demonstrated in vivo and in vitro [11–14] Recently it became clear that the FeS cluster of [2Fe-2S]ÆFNR is also labile in vivo and in vitro in the presence of air and that FNR loses the [2Fe-2S] cluster [15,16] The chemical reactions of O2 and of peroxide causing cluster destruction have been studied [15,17] ApoFNR, which is devoid of FeS clusters, is a further form of FNR and obtained during isolation of FNR and by prolonged exposure of [4Fe-4S]ÆFNR to air [18–20] It is not known, however, whether apoFNR

is a preparatory artifact, or whether its formation

Keywords

apoFNR; cysteine disulfides; Escherichia

coli; fumarate nitrate reductase regulator;

oxygen sensing

Correspondence

G Unden, Johannes Gutenberg-Universita¨t

Mainz, Institut fu¨r Mikrobiologie und

Weinforschung, Becherweg 15,

55 099 Mainz, Germany

Fax: +49 6131 3922695

Tel: +49 6131 3923550

E-mail: unden@uni-mainz.de

*These authors contributed equally to the

work

(Received 1 June 2005, revised 24 June

2005, accepted 1 July 2005)

doi:10.1111/j.1742-4658.2005.04840.x

The active form of the oxygen sensor fumarate nitrate reductase regulator (FNR) of Escherichia coli contains a [4Fe-4S] cluster which is converted to

a [2Fe-2S] cluster after reaction with air, resulting in inactivation of FNR Reaction of reconstituted [4Fe-4S]ÆFNR with air resulted within 5 min in conversion to apoFNR The rate was comparable to the rate known for [4Fe-4S]ÆFNR⁄ [2Fe-2S]ÆFNR cluster conversion, suggesting that apoFNR is

a product of [2Fe-2S]ÆFNR decomposition and a final form of air-inacti-vated FNR in vitro Formation of apoFNR and the redox state of the cysteinyl residues were determined in vitro by alkylation FNR contains five cysteinyl residues, four of which (Cys20, Cys23, Cys29 and Cys122) ligate the FeS clusters Alkylated FNR and proteolytic fragments thereof were analyzed by MALDI-TOF ApoFNR formed by air inactivation of [4Fe-4S]ÆFNR in vitro contained one or two disulfides Only disulfide pairs Cys16⁄ 20 and Cys23 ⁄ 29 were formed; Cys122 was never part of a disulfide The same type of disulfide was found in apoFNR obtained during isolation

of FNR, suggesting that cysteine disulfide formation follows a fixed pattern ApoFNR, including the form with two disulfides, can be reconsti-tuted to [4Fe-4S]ÆFNR after disulfide reduction The experiments suggest that apoFNR is a major form of FNR under oxic conditions

Abbreviations

CM, carboxymethyl; DTNB, 5,5¢-dithiobis(2-nitrobenzoate); FNR, fumarate nitrate reductase regulator; GnHCl, guanidinium hydrochloride; GST, glutathione S-transferase; TFA, trifluoroacetic acid.

is of functional relevance The recent demonstration

that [2Fe-2S]ÆFNR disappears within few minutes

from cells of E coli under exposure to air [15,16],

could be an indication that significant amounts of

apo-FNR are found in bacteria The assumption prompted

our studies to test whether apoFNR is formed at rates

comparable to the air-induced [4Fe-4S]⁄ [2Fe-2S]

clus-ter conversion and the loss of [2Fe-2S] from FNR

Comparable rates would indicate that apoFNR is the

product formed from [2Fe-2S]ÆFNR in vivo [15,16]

and in vitro Therefore the conditions and kinetics

for the formation of apoFNR from active FNR were

analyzed

Recently it has been shown that various forms of

apoFNR exist in vitro which differ in the redox state

of the cysteinyl residues and their availability for

reconstitution to [4Fe-4S]ÆFNR [18] Three of the

cys-teine ligands of the FeS cluster of FNR are located at

the N-terminal end (Cys20, Cys23 and Cys29), the

fourth (Cys122) is close to the centre of the protein

[21–23] The fifth residue (Cys16) is not essential The

redox state of the cysteinyl residues of apoFNR should

be relevant for function and properties of the protein

Therefore the redox state of the cysteinyl residues of

the various forms of apoFNR – ‘aerobic’ and

‘anaer-obic’ apoFNR, and apoFNR obtained by air-induced

inactivation of [4Fe-4S]ÆFNR – was determined in

order to identify cysteinyl residues which are sensitive

to oxidation and disulfide formation ‘Aerobic’ and

‘anaerobic’ apoFNR are obtained by the isolation

of the protein under oxic or anoxic conditions

[18,22,24,25] The cysteine disulfides in the three forms

of apoFNR showed a distinct pattern of disulfides,

whereas [4Fe-4S]ÆFNR (and [2Fe-2S]ÆFNR) contained

no disulfides Thus the disulfides in apoFNR can be

used as a specific indicator for apoFNR formation

from [4Fe-4S]ÆFNR during air inactivation In this way

it was possible to demonstrate that reaction of

[4Fe-4S]ÆFNR with air generates apoFNR in vitro with

rates comparable to [4Fe-4S]⁄ [2Fe-2S] cluster

conver-sion [16,17,26] suggesting that apoFNR is the final

form of FNR under oxic conditions

Results

Redox state of the cysteinyl residues in apoFNR

and in reconstituted [4Fe-4S]ÆFNR

ApoFNR that was devoid of Fe and acid-labile sulfur

(not shown) was obtained by isolation of FNR from

E coli under oxic and anoxic conditions (‘aerobic’ or

‘anaerobic’) In SDS gel electrophoresis without

redu-cing agents, anaerobic apoFNR formed one band with

the typical molecular mass of FNR (Mr30 000) Aero-bic apoFNR showed an additional band of Mr 27 000 (not shown) as described earlier [22] The latter form disappeared when the sample was incubated with dithiothreitol or 2-mercaptoethanol, whereas the

Mr 30 000 protein was not affected In aerobic and anaerobic apoFNR 2.8 and 4.0 from the total of five cysteinyl residues reacted with 5,5¢-dithiobis-nitro-benzoate (DTNB) (Table 1) or iodoacetate after dena-turing by guanidinium hydrochloride (GnHCl), and were thus in the thiol state This suggests that aerobic apoFNR contains a portion with an (additional) disul-fide which has a more condensed structure and higher mobility in SDS gel electrophoresis

After reaction with iodoacetic acid, the carboxy-methyl derivatives were analyzed by MALDI-TOF mass spectroscopy Aerobic and anaerobic apoFNR showed a molecular mass of 28 112 ± 14 Da before modification (not shown) which is close to the predic-ted molecular mass of the recombinant FNR of

28112 Da (FNR plus N-terminal Gly-Ser extension) The alkylated aerobic apoFNR produced three major peaks of 28 169 Da, 28 284 Da, and 28 398 Da (Fig 1A), corresponding to one-, three- and fivefold alkylated FNR, as each carboxymethyl (CM) residue increases the molecular mass by 58 Da No unmodified apoFNR was detected Threefold alkylated apoFNR showed the most intense signal The MALDI-TOF spectrum of anaerobic apoFNR consisted of one major signal at 28 408 Da after alkylation equivalent to five-fold alkylated apoFNR, and a minor signal of three-fold alkylated FNR (Fig 1B) Therefore, aerobic and anaerobic apoFNR are mixtures of FNR with one, three and five, and five and three cysteine thiol resi-dues, respectively

In reconstituted [4Fe-4S]ÆFNR up to four cysteinyl residues reacted with DTNB (Table 1) The residues

Table 1 Thiol and disulfide cysteinyl residues in apoFNR (aerobi-cally or anaerobi(aerobi-cally prepared), reconstituted [4Fe-4S]ÆFNR, and air-inactivated [4Fe-4S]ÆFNR The contents of cysteine thiols were determined with DTNB or [ 14 C]iodoacetate The number of cystei-nyl residues present in the oxidized state (‘Disulfide S’) were calcu-lated as the difference to the total of five cysteinyl residues present in FNR The thiol contents are the mean of three experi-ments (max deviation 25%).

Thiol (mol ⁄ mol FNR) Disulfide S

a Fig 7.

were accessible to labeling only after denaturing of the

protein In MALDI-TOF analysis, the alkylated

pro-tein gave one major signal of 28 395 Da corresponding

to fivefold alkylated FNR (FNR-CM5, theoretical

molecular mass 28 402 Da) (not shown) Four- and

threefold alkylated FNR was found only in traces

In this way, [4Fe-4S]ÆFNR (and presumably

[2Fe-2S]ÆFNR) differ clearly from apoFNR by the lack of

cysteinyl disulfides which can be used for

differenti-ation of apoFNR and [4Fe-4S]ÆFNR in vitro by

labe-ling of cysteinyl thiol residues with iodoacetate after

denaturing the protein

Kinetics of cysteinyl residue oxidation during

inactivation of [4Fe-4S]ÆFNR by air Reconstituted

[4Fe-4S]ÆFNR was exposed to air, and after various

times samples were analyzed for the number of

reduced cysteinyl residues by reacting the protein with

[14C]iodoacetate (Fig 2) GnHCl was included at the

same time to destabilize the FeS clusters and to make

the cysteinyl residues accessible to alkylation In

anae-robic, reconstituted FNR about four cysteinyl residues

were labeled by this method After addition of air, the

amount of reactive cysteinyl residues increased slightly

for about 2 min Then the amount decreased to about

two residues within the next 3 min, corresponding to

an average of three cysteinyl residues in the oxidized

state Under anoxic conditions no change in the num-ber of reactive cysteine residues was observed Exten-ded incubation with air gave no further decrease of reactive thiols The result demonstrates that, after a lag phase of about 2 min, air causes formation of disulfides in FNR which is finished within about

3 min Formation of the disulfides has to be accom-panied by the loss of the FeS cluster of FNR due to the loss of two or four ligands of the FeS cluster This type of kinetics was only obtained when excess Fe ions were removed by EDTA, presumably due to reaction

of Fe ions with cysteinyl residues

Defined cysteine disulfides in aerobic and anaerobic apoFNR

Alkylated forms of aerobic and anaerobic apoFNR were digested by proteases, and the peptides were iso-lated and characterized by MALDI-TOF Modified trypsin cleaves the protein at the C-terminal site of arginine and lysine, and the tryptic digest of FNR is predicted to contain the four N-terminal Cys residues

in the peptide comprising amino acids 11–48 (Pep11⁄ 48) Cys122 is found in a peptide of amino acids 78–135 (Pep78⁄ 135) The tryptic digest of aerobic apoFNR contained unmodified Pep11⁄ 48 (4258 Da) and two derivatives with two and four carboxymethyl groups, respectively (Fig 3A) Pep78⁄ 135 with Cys122

Fig 1 MALDI-TOF spectra of aerobically (A) and anaerobically (B)

prepared and carboxymethylated apoFNR The samples of apoFNR

were alkylated with 10 m M iodoacetate under denaturing conditions

in 4 M GnHCl, purified by solid phase extraction and subjected to

MALDI-TOF MS analysis The spectra were taken using sinapinic

acid as matrix in the linear mode of the instrument (for details see

Experimental procedures).

Fig 2 Measurement of reactive cysteinyl residues during air-inacti-vation of reconstituted [4Fe-4S]ÆFNR Aerobic apoFNR was reconsti-tuted, transferred to a Petridish and incubated under air (0 min) At the given time-points, samples were removed and denatured in a solution of GnHCl (4 M ) and [14C]iodoacetate (12 m M and 43 BqÆ mmol)1 iodoacetate) The protein was precipitated and washed with methanol + chloroform [31] and used for measurement of pro-tein and radioactivity (mean of three independent experiments).

was found only as the alkylated form No adduct of

Pep11⁄ 48 with Pep78 ⁄ 135 was present, ruling out the

presence of a disulfide bridge between both peptides

Thus aerobic apoFNR is a mixture of proteins with

zero, one or two disulfide bonds within the four

N-terminal cysteinyl residues When anaerobic apoFNR was digested with trypsin, only four- and twofold alkylated, but no unmodified Pep11⁄ 48 was found (Pep11⁄ 48-CM4and Pep11⁄ 48-CM2) (Fig 3B)

Protease AspN cleaves N-terminal to aspartate

By this cleavage, Pep1⁄ 21 containing Cys16 and Cys20, Pep22⁄ 39 with Cys23 and Cys29, and Pep102 ⁄ 129 con-taining Cys122 were generated (Table 2) When the peptides were produced from aerobic apoFNR after alkylation, Pep22⁄ 39 was found as the unmodified and, in small amounts, also as the twofold alkylated species Pep1⁄ 21 was present in the unmodified state,

as well as modified with two alkyl residues Thus Cys16⁄ Cys20 and Cys23 ⁄ Cys29 formed disulfides in aerobic apoFNR Pep102⁄ 129, on the other hand, was found only in the alkylated form, demonstrating again that Cys122 was not involved in disulfide formation

No peptides corresponding to the combination of Pep1⁄ 21, Pep22 ⁄ 39 or Pep102 ⁄ 129 were found, and thus only disulfides Cys16⁄ Cys20 and Cys23 ⁄ Cys29 were present within aerobic apoFNR

Pep1⁄ 21 and Pep22 ⁄ 39 were detected from anaerobic apoFNR in the unmodified as well as the twofold alkylated form and, therefore, Cys16⁄ Cys20 and Cys23⁄ Cys29 could also be responsible for apoFNR with one disulfide Cys23⁄ 29, however, was found at significantly lower levels than in aerobic apoFNR, sug-gesting that the Cys16⁄ 20 disulfide is formed preferen-tially to the Cys23⁄ 29 disulfide

Quantification of disulfide and thiol containing peptides after HPLC separation

The peptides of the AspN digest with the cysteinyl residues in the disulfide or thiol state were quantified

Fig 3 MALDI-TOF spectra of peptides derived from

carboxymeth-ylated aerobic (A) and anaerobic (B) apoFNR (trypsin digest) The

samples (carboxymethylated tryptic digest of aerobic or anaerobic

apoFNR) were purified by solid phase extraction and analyzed by

MALDI-TOF MS in the reflector mode of the instrument using

a-cyano-4-hydroxycinnamic acid as matrix Masses (m ⁄ z) of

cysteinyl residues containing tryptic peptides Pep11 ⁄ 48 (with

Cys16, Cys20, Cys23, Cys29) and Pep78 ⁄ 135 (with Cys122):

Pep11⁄ 48-CM 0 4258 in (A) (predicted 4259); Pep11 ⁄ 48-CM 2 4375

in (A) and 4374 in (B) (predicted 4375); Pep11 ⁄ 48-CM 4 4494 in (A)

and 4493 in (B) (predicted 4491); Pep78 ⁄ 135-CM 1 6248 in (A) and

6244 in (B) (predicted 6244) The predicted masses were obtained

from the mass of the peptide plus the mass increase of 58 after

alkylation per cysteinyl residues by iodoacetic acid.

Table 2 Mass of fragments of aerobically and anaerobically prepared apoFNR after treatment with iodoacetic acid and digestion with prote-ase AspN The numbering of the peptides gives the first and the last amino acid residue according to numbering in FNR The mass of the fragments and of their alkylated forms were determined by MALDI-TOF spectroscopy Pep1 ⁄ 21 (with Cys16 and Cys20) contains in addition the two N-terminal Gly-Ser residues derived from the GST¢-¢FNR fusion Pep22 ⁄ 39 contains Cys23 and Cys29, Pep102 ⁄ 129 Cys122 The cal-culated masses were obtained from the mass of the peptide and a mass increase of 58 after alkylation by iodoacetic acid per cysteinyl resi-due ND, not detected.

Cys-containing fragments Thiol Disulfide

Mass for alkylated peptides of apoFNR Calculated (m ⁄ z) Aerobic (m ⁄ z ± 3) Anaerobic (m ⁄ z ± 3)

a Fragments can be detected after reversed phase HPLC (Table 3).

after alkylation and proteolytic digestion The peptides

were separated by reversed-phase HPLC

chromatogra-phy (Fig 4), and the peptides in the peaks were

identi-fied by MALDI-TOF The amount of peptide was

quantified from the peak area of the HPLC eluate

(Fig 4) The peptides Pep11⁄ 21 (Cys16, Cys20) and

Pep22⁄ 39 (Cys23, Cys29) from aerobic and anaerobic

apoFNR were found in the noncarboxymethylated

(disulfide) form as well as with two carboxymethyl

groups (Fig 4) The peptide with Cys16⁄ Cys20 was

present to 65% in the oxidized (disulfide) form in

aero-bic and in anaeroaero-bic apoFNR (Table 3) The 23⁄ 29

disulfide in Pep22⁄ 39 was significantly increased in aerobic compared with anaerobic apoFNR (Table 3) which represented the only distinct differences between both forms of apoFNR Generally, a smaller portion

of the Cys23⁄ Cys29 than of the Cys16 ⁄ Cys20 residues was in the disulfide state, suggesting that the Cys16⁄ 20 disulfide is formed preferentially

Redox state of cysteinyl residues during

inactivation of [4Fe-4S]ÆFNR with air

The redox state of the cysteinyl residues of [4Fe-4S]ÆFNR after inactivation by air (Fig 2) was determined After reaction with iodoacetate, FNR of molecular mass 28 262 Da was found which most prob-ably represents FNR with one disulfide and three thiol residues (theoretical molecular mass 28 286 Da) Devia-tion of experimental and expected molecular mass by

24 Da is due to a variation in absolute mass (± 28 Da)

by nonspecific absorption of ions Using [14 C]iodoace-tate, FNR with two labeled cysteine thiols was identified after inactivation with air (Fig 2 and Table 1) Alto-gether, the experiments show that air-inactivated [4Fe-4S]ÆFNR is a mixture of apoFNR with one disul-fide plus three cysteine thiol residues, and FNR with two disulfides and one cysteine thiol

The air inactivated and alkylated FNR of the experi-ment from Fig 2 was digested with AspN or trypsin and analyzed by MALDI-TOF for the presence of alkylated peptides In AspN digests, peptides Pep1⁄ 21 and Pep22⁄ 39 with 2555 and 2062 Da were found which are characteristic of the presence of disulfides Cys16⁄ Cys20 and Cys23⁄ Cys29, respectively (not shown) In the tryptic digest, peptides with masses indicative for disulfides were found (Fig 5), suggesting that up to two disulfides are formed by air-inactivation

of FNR in vitro This again shows that the air-inacti-vated FNR is a mixture of apoFNR with one and two disulfides, and the disulfides are the same as in aerobic apoFNR (Cys16⁄ Cys20 and Cys23 ⁄ Cys29)

Discussion

Significance of apoFNR [4Fe-4S]ÆFNR is converted rapidly to apoFNR after exposure to air and a lag phase of about 2 min The lag phase presumably includes the [4Fe-4S]⁄ [2Fe-2S] conversion, which has no direct effect on the redox state of the cysteinyl residues The rate of apoFNR formation is similar to that of [4Fe-4S]⁄ [2Fe-2S] con-version, indicating that apoFNR is a significant prod-uct of FNR inactivation by air

Fig 4 Peptides of aerobic apoFNR after carboxymethylation,

tryp-sin and AspN digestion and reversed-phase chromatography The

sample buffer was changed by gel filtration on a Nap10 column

and then subjected to trypsin digestion The digest was separated

by gel filtration on a Superdex Peptide column The fraction

contain-ing peptide 11 ⁄ 48 (containing Cys16, Cys20, Cys23, Cys29) was

digested with AspN and separated by reversed phase

chromatogra-phy To identify the peptides in the individual chromatographic

frac-tions, each fraction was subjected to MALDI-TOF analysis The

corresponding peptides in the fractions are indicated.

Table 3 Quantitative evaluation of thiol and disulfide containing

pep-tides of aerobically and anaerobically prepared apoFNR Aerobically

or anaerobically prepared apoFNR were incubated with GnHCl +

iodoacetate and digested with trypsin, and after separation on

Sepha-dex Peptide column, by AspN The desalted peptides were separated

by reversed phase HPLC chromatography (AquaPore RP300) (Fig 4).

Relevant peak fractions were subjected to MALDI-TOF to identify

the peptides and the degree of alkylation The relative contents of

the disulfide and the dithiol forms of one peptide from one

chromato-gram was evaluated from the absorption of the corresponding

peaks and the peak areas from three independent experiments and

samples The data are the mean of three independent experiments

(max deviation 10%).

Peptide

Aerobic apoFNR Anaerobic apoFNR Pep-SS Pep-CM 2 Pep-SS Pep-CM 2

[4Fe-4S]ÆFNR shows a complex response to the

pres-ence of air (Fig 6 gives an overview), and the response

differs in vitro and in vivo The reactions of the FeS

cluster-containing forms of FNR were studied by

Mo¨ssbauer spectroscopy, whereas information on

apo-FNR was obtained via the redox state of the cysteine

residues [4Fe-4S]ÆFNR is converted to [2Fe-2S]ÆFNR under oxic conditions within few minutes [13,16,17,26], and the slower reaction in vivo is due to experimental conditions [13] It has been estimated from expression studies that inactivation of FNR by air (which compri-ses the [4Fe-4S]ÆFNR⁄ [2Fe-2S]ÆFNR conversion) takes place within 4 min 30 s [16], which supports the more rapid in vitro data [2Fe-2S]ÆFNR was shown to be rather stable in vitro in the presence of air, whereas

H2O2 caused a rapid disintegration of the cluster [15,16; Fig 6] In vivo, the [2Fe-2S] cluster disappeared within 15 min (or less) in the presence of air As a result, aerobically grown E coli contains no [2Fe-2S]ÆFNR or ([4Fe-4S]ÆFNR) [16] Aerobically grown

E coli contains FNR protein in amounts which are similar to, or even higher than, anaerobically grown bacteria [15,27] It is suggested that the FNR protein present under these conditions consists mainly of apo-FNR In aerobically grown E coli, O2 tension appears

to be similar to that in the external growth medium [7,9,10] Therefore, with respect to O2 supply and effective O2 tension, the in vivo conditions are compar-able to the in vitro conditions used here for FNR inactivation

Fig 5 Redox state of Cys residues in

Pep78⁄ 135 (A) and Pep11 ⁄ 48 (B) of

recon-stituted [4Fe-4S]ÆFNR after air-inactivation

trypsin digestion Reconstituted and

subse-quently air-inactivated [4Fe-4S]ÆFNR was

denatured in 4 M GnHCl and alkylated with

iodoacetate After solid phase extraction the

protein was digested by trypsin, separated

by gel filtration, and analyzed by

MALDI-TOF MS (A) Pep78 ⁄ 135, containing

Cys122, with one CM-group (predicted

mass 6244 Da) (B) Pep11⁄ 48 in the

unmodi-fied form (predicted mass 4259 Da)

contain-ing Cys16⁄ Cys20 and Cys23 ⁄ Cys29 as the

disulfides Peptide of mass 4411.9

corres-ponds to Pep10 ⁄ 48 which contains Arg10

in addition (predicted mass 4416) which

is obtained with low yield under some

conditions.

Fig 6 Reaction steps and time required for conversion of

[4Fe-4S]ÆFNR to apoFNR The scheme shows species of FNR

involved in the conversion to apoFNR, species not directly

meas-ured for the respective reaction are given in broken lines The

quoted times are either t1⁄ 2values or the times required for

con-version between both forms The corresponding references are

given in brackets.

ApoFNR is a product of the reaction of

([4Fe-4S]ÆFNR) with air

The in vitro rate for the conversion of [4Fe-4S]ÆFNR

to apoFNR (via [2Fe-2S]ÆFNR) is either similar to the

rates shown for the cluster conversions or more rapid

(Fig 6) ApoFNR formation is the counterpart to the

disappearance of [2Fe-2S]ÆFNR in the bacteria [16]

The presence of significant amounts of apoFNR in the

bacteria has to be demonstrated, but preliminary

results indicate that aerobically grown E coli contain

significant amounts of apoFNR (S Achebach and

G Unden, unpublished results) ApoFNR containing

high levels of disulfides can be used successfully for

reconstitution of [4Fe-4S]ÆFNR in vitro [18], further

supporting the physiological significance of apoFNR

in bacteria

Formation of apoFNR represents a second step of

FNR inactivation and transfers FNR to a functional

state which is less sensitive to reactivation by

short-term or partial anoxic conditions than [2Fe-2S]ÆFNR

Desensitizing of FNR would be significant for E coli

growing on a long-term basis under oxic conditions to

avoid production of anaerobic metabolic systems in

response to short-term air depletion

Different forms of apoFNR

The forms of apoFNR obtained during aerobic or

anaerobic preparation and by in vitro inactivation by

air differed by the redox state or contents of

Cys16⁄ Cys20 and Cys23 ⁄ Cys29 disulfides (Fig 7) The

cysteinyl residues were not oxidized by air to sulfenic

or sulfonic acids, as peptides with the corresponding

mass increases were not detected Formation of

sulfen-ic and sulfonsulfen-ic acid to a larger extent is also unlikely

as the protein can be reconstituted to active FNR using sulfhydryl reducing agents like dithiothreitol The cysteinyl residues play a central role in the func-tion of FNR, and their redox state was tested by chemical modification and MALDI-TOF mass spec-troscopy which gave consistent results The cysteine disulfides could be used as indicators for apoFNR formation, for which other good biochemical markers are not available In the presence of reducing agents such as dithiothreitol, or glutathione as in the cyto-plasm of E coli, the cysteine disulfides are expected to exist in the thiol state

Knowledge of the type of cysteinyl disulfides in FNR provides important information about the bio-chemistry and properties of the protein, the function

of which relies mostly on the cysteine residues and the FeS clusters bound by the cysteine residues Cysteinyl disulfides were formed only between distinct pairs of residues (Cys16⁄ 20 and Cys23 ⁄ 29), whereas Cys122 was never part of a disulfide (Fig 7) This could be related to a specific role of Cys122 which is also essential for function and cluster assembly [28] FNR-SS-(SH)3, which contains one disulfide, was a mixture of proteins with either the Cys16⁄ Cys20 or the Cys23⁄ Cys29 disulfide The Cys16 ⁄ Cys20 disulfide is formed preferentially, but there is no clear order in the formation of the two disulfides Formation of the pairs might reflect suitable spatial vicinity, lacking accessibil-ity of Cys122, or functional differences of the cysteinyl residues Aerobic apoFNR with high disulfide content [presumably due to the presence of FNR-(SS)2-SH] was shown earlier [18] to have an extended lag phase

Fig 7 Schematic presentation of FNR and

of cysteinyl thiol and disulfide residues in different forms of FNR The scheme shows the cysteine thiols and disulfides in different forms of FNR, and their approximate contri-bution to different functional forms of FNR (active [4Fe-4S]ÆFNR, air-inactivated FNR, aerobic and anaerobic apoFNR) The cystei-nyl residues (Cys16, Cys20, Cys23, Cys29, Cys122) are presented by their thiol (–SH) or disulfide (–SS–) residues; FNR-SS-(SH) 3 , e.g stands for apoFNR with one disulfide and three cysteine thiol residues –, not pre-sent; +, prepre-sent; ++, major component.

in the reconstitution of [4Fe-4S]ÆFNR from apoFNR

in vitro The increased lag phase could be overcome

by the addition of dithiothreitol and protein disulfide

reductases

Experimental procedures

Isolation and reconstitution of FNR

FNR was produced and isolated as a GST¢-¢FNR fusion

protein from E coli CAG627pMW68 [24] GST¢-¢FNR

bound to glutathione-Sepharose 4B (1.5 mL bed volume)

was digested for 2 h at 20
C with 20 U thrombin in 1 mL

buffer C (50 mm Tris⁄ HCl, pH 7.6) and then eluted from

the column in 3 mL buffer C (without addition of

glutathi-one) For the isolation of anaerobic apoFNR, anoxic

buff-ers prepared and maintained in an anaerobic chamber were

used and the whole procedure starting with incubation of

the bacteria was performed under anoxic conditions [24]

Aerobic apoFNR was prepared in the same way, but all

buffers were air saturated and all steps were performed

under air FNR obtained from GST-FNR in this way

con-tains a Gly-Ser extension in front of the N-terminal

Met-Ile-Pro of wild-type FNR Azotobacter vinelandii (NifSAV)

was isolated from E coli BL21(DE3) containing a nifSAV

expression plasmid for NifSAV production [24,29]

[4Fe-4S]ÆFNR was reconstituted under anoxic conditions

[3,24] in a mixture containing isolated apoFNR, 0.3 mm

Fe(II), 2 mm cysteine and NifSAV (1 lg⁄ 20 lg FNR) The

number of thiol groups was determined with

5,5¢-dithiobis-nitrobenzoate (DTNB) [30] or by the incorporation of

[14C]iodoacetate

Carboxymethylation of FNR

For alkylation of anaerobic apoFNR, 250–350 lg FNR

were anoxically incubated for 30 min with 4 m guanidinium

hydrochloride (GnHCl) and 10 mm iodoacetate, buffer

(25 mm Tris⁄ HCl, pH 7.6), at room temperature in the

dark Prior to MALDI-TOF MS, low molecular mass

con-taminations were removed by solid phase extraction

Alky-lation of aerobic apoFNR was performed in the same way,

but all buffers were air saturated and the experiments were

done under air

AspN digest

Carboxymethylated protein was desalted by gel filtration

using Nap10 columns (Amersham Pharmacia Biotech,

Pis-cataway, NJ, USA) equilibrated with 1 m GnHCl in 50 mm

ammonium acetate, pH 8.0 The sample was added and

frac-tions of 500 lL each were collected Fracfrac-tions containing

the protein were pooled and digested with 1% (w⁄ w)

endo-proteinase AspN (sequencing grade, Roche, Indianapolis,

IN, USA) for 5 h at 37
C which cleaves at the N-terminal end of aspartyl residues The samples were desalted by solid phase extraction and subsequently dried by vacuum centrifugation

Trypsin digest The carboxymethylated protein was desalted by gel filtra-tion on a Nap10 column equilibrated with 10% (v⁄ v) aceto-nitrile in 50 mm ammonium acetate, pH 8.6 The eluted protein was combined and digested with 7–9% (w⁄ w) modi-fied trypsin (sequencing grade, Roche) for 8 h at 37
C which cleaves at the C-terminal end of arginyl or lysyl resi-dues After digest, the peptides were dried by vacuum cen-trifugation and stored at)20
C

Time dependent cysteinyl accessibility during air-inactivation of [4Fe-4S]ÆFNR

Aerobically prepared apoFNR was reconstituted under anoxic conditions as described above Reconstitution was followed spectroscopically at 420 nm using the absorbance

at 280 nm as reference After complete reconstitution,

5 mm EDTA was added After 30–50 min the sample (0.9 mL) was placed into a Petri dish which was transferred

to an atmosphere of air with gentle shaking Samples (50 lL) were withdrawn prior and after 2 min, 5 min,

10 min and 20 min of aeration, mixed immediately with

50 lL of 8 m GnHCl (final concentration 4 m) and [14C]iodoacetate (final concentration 12 mm, specific radio-activity 43 BqÆmmol)1, etc.) After 10 h the protein was pre-cipitated and washed carefully with methanol–chloroform [31] The protein concentration was determined using the Bradford assay [32] and the radioactivity was measured in

a scintillation counter Radioactivity was corrected for not incorporated radioactivity by measuring and subtracting the radioactivity in identically treated samples lacking apo-FNR

Solid phase extraction Protein or peptide samples were applied to C18-Sep Vac 1cc

50 mg cartridges (Waters, Milford, MA, USA) equilibrated with 0.1% trifluoroacetic acid (TFA) The columns were washed with 0.1% TFA and proteins or peptides were eluted with 60% (v⁄ v) acetonitrile in 0.1% (v ⁄ v) TFA

HPLC separation and quantification of the peptides

The carboxymethylated protein was subjected to solid phase extraction, eluted, dried by vacuum centrifugation and dissolved in 0.1% (v⁄ v) TFA and 4 m GnHCl The samples were desalted by gel filtration on NAP 10 columns

equilibrated with 10% (v⁄ v) acetonitrile in 50 mm

ammo-nium acetate, pH 8.6 The protein was then digested with

5% (w⁄ w) modified trypsin (sequencing grade, Roche) for

11 h at 37
C The trypsin digest was subjected to HPLC

separation over a gel filtration column (SuperdexTMPeptide

10⁄ 30) operated in 0.1% (v ⁄ v) TFA in 10% (v ⁄ v)

acetonit-rile in order to separate the large (4 and 6 kDa)

cysteine-containing from the bulk peptides (< 3 kDa) Fractions

containing these peptides were identified by mass

spectro-metry, pooled and dried The peptides were re-dissolved in

1 m GnHCl in 20 mm Tris⁄ HCl, pH 8, containing 2 lg of

endoproteinase AspN The samples were digested for 9 h at

37
C The resulting peptides were separated by reversed

(2.1· 100 mm) and monitored at 215 nm Individual

pep-tides were collected manually and analyzed by

MALDI-TOF MS

MALDI-TOF MS

Mass spectra of proteins and peptides were collected using

a Perkin-Elmer Voyager-RP⁄ DE mass spectrometer

(Per-septive Biosystems, Wiesbaden, Germany) In order to

avoid an interfering binding of salts to FNR, the protein

was carefully desalted by solid-phase extraction prior to

MALDI-TOF MS Samples thus obtained were either

dissolved in 67% (v⁄ v) acetonitrile in 0.1% (v ⁄ v) TFA or

matrix solutions yielding final concentrations of 1–10 pmolÆ

lL)1 protein or peptides Equal volumes of samples and

saturated solutions of either sinnapinic acid (proteins) or

a-cyano-4-hydroxycinnamic acid in 0.1% (v⁄ v) TFA, 67%

(v⁄ v) acetonitrile were mixed on the sample slide and dried

in a stream of air Proteins were measured in the positive

linear mode of the instrument at an acceleration voltage of

25 kV using a grid voltage of 89% and a delay time of

300 ns Peptide spectra were collected in the positive

reflec-tor mode at an acceleration voltage of 20 kV using a grid

voltage of 58% and a delay time of 100 ns

Acknowledgements

The authors thank R Thauer for the access to

MALDI-TOF MS at the Max-Planck-Institut fu¨r

Ter-restrische Mikrobiologie, Marburg The work was

sup-ported by grants of Deutsche Forschungsgemeinschaft

and of the Fonds der Chemischen Industrie

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