Báo cáo khoa học: Subunit composition of the glycyl radical enzyme p-hydroxyphenylacetate decarboxylase doc

Moreover, the decarboxylase gene hpdB was located in a putative operon together with a gene encoding an activating enzyme hpdA, which is required to form the kinetically stable glycyl ra

Subunit composition of the glycyl radical enzyme

A small subunit, HpdC, is essential for catalytic activity

Paula I Andrei1, Antonio J Pierik1, Stefan Zauner2, Luminita C Andrei-Selmer3and Thorsten Selmer1

1 Laboratorium fu¨r Mikrobiologie, Fachbereich Biologie, Philipps-Universita¨t, Marburg, Germany; 2 Institut fu¨r Zellbiologie und angewandte Botanik, Fachbereich Biologie, Philipps-Universita¨t, Marburg, Germany;3Institut fu¨r Klinische Immunologie und Transfusionsmedizin, Justus-Liebig Universita¨t Giessen, Germany

p-Hydroxyphenylacetate decarboxylase from Clostridium

difficilecatalyses the decarboxylation of

p-hydroxyphenyl-acetate to yield the cytotoxic compound p-cresol The three

genes encoding two subunits of the glycyl-radical enzyme

and the activating enzyme have been cloned and expressed

in Escherichia coli The recombinant enzymes were used

to reconstitute a catalytically functional system in vitro In

contrast with the decarboxylase purified from C difficile,

which was an almost inactive homo-dimeric protein (b2), the

recombinant enzyme was a hetero-octameric (b4c4),

cata-lytically competent complex, which was activated using

endogenous activating enzyme from C difficile or recom-binant activating enzyme to a specific activity of 7 UÆmg)1 Preliminary results suggest that phosphorylation of the small subunit is responsible for the change of the oligomeric state These data point to an essential function of the small subunit

of the decarboxylase and may indicate unique regulatory properties of the system

Keywords: Clostridium difficile; cresol; glycyl radical enzymes; S-adenosyl-methionine radical enzymes; Tanne-rella forsythensis

Clostridium difficile is a spore forming, strict anaerobic

bacterium that causes gastrointestinal infections in humans

ranging from asymptomatic colonization to severe

diar-rhoea, pseudomembranous colitis, toxic megacolon, colon

perforation and occasionally death [1] C difficile-associated

diarrhoea is very common in hospitalized patients,

partic-ularly after the normal intestinal flora has been disturbed by

an antibiotic or an antineoplastic treatment [2,3]: the normal

gut microbiota has to be disrupted before C difficile

infection can become established The production of toxic

fermentation end products may allow an ongoing

suppres-sion of the endogenous microflora and therefore may play an

important role in the progression of the disease

The formation and tolerance of p-cresol by C difficile as

the end product of tyrosine fermentation is well known [4,5]

The enzyme responsible is p-hydroxyphenylacetate

decarb-oxylase (Hpd, E.C 4.1.1.-) [6] which was previously purified

in an almost inactive state [7] Based on the N-terminal

amino acid sequence of the protein, an ORF was detected

in the unfinished genome of C difficile strain 630 provided

by the C difficile Sequencing Group at the Sanger Center The encoded 902-amino acid protein was most similar to pyruvate formate lyase-like proteins of unknown function and showed a typical glycyl radical consensus sequence motif (VRVAGF) in the C-terminal region Moreover, the decarboxylase gene (hpdB) was located in a putative operon together with a gene encoding an activating enzyme (hpdA), which is required to form the kinetically stable glycyl radical

in the active enzyme

In this communication we report the identification of a hitherto unknown small subunit (HpdC) of the decarboxy-lase, which is essential for catalytic activity and may provide the unique regulatory properties of the Hpd system

Materials and methods

Materials

C difficile(DSM 1296T) was purchased from the German Collection of Micro-organisms and Cell Cultures (DSMZ, Braunschweig, Germany) Escherichia coli strains and plasmids were obtained from commercial sources Chemi-cals were purchased from commercial sources and were of the highest grade available

Organisms and cultivation

C difficilewas cultivated as described previously [7] Unless otherwise stated, E coli strains were grown on Luria– Bertani (LB) agar plates or LB media supplemented with the required antibiotics at 28–30
C

Correspondence to T Selmer, Laboratorium fu¨r Mikrobiologie,

Fachbereich Biologie, Philipps-Universita¨t, Karl-von-Frisch Str.,

D-35032 Marburg, Germany.

Fax: + 49 6421 2828979, Tel.: + 49 6421 2825606,

E-mail: selmer@staff.uni-marburg.de

Abbreviations: LB, Luria–Bertani; Hpd, p-hydroxyphenylacetate

decarboxylase; SAM, S-adenosyl-methionine; TFA, trifluoroacetic

acid; RBS, ribosome binding sites.

Enzymes: p-Hydroxyphenylacetate decarboxylase (EC 4.1.1.-);

pyruvate formate lyase (EC 2.3.1.54); ribonucleotide reductase

(EC 1.17.4.1); benzylsuccinate synthase (EC 4.1.-.-).

(Received 8 January 2004, revised 15 March 2004,

accepted 6 April 2004)

Cloning and sequencing of the genes

The individual cloning steps were carried out in E coli

DH5a or GM 2159 strains Genomic DNA of C difficile

strain DSM 1296T was used as a template for PCR

amplification of the hpd-genes The primers were deduced

from the genomic sequence provided by the Sanger Centre

C difficile Sequencing Group (http://www.sanger.ac.uk/

Projects/C_difficile/blast_server.shtml) KpnI and ClaI

endonuclease cleavage sites were introduced upstream and

downstream of the coding sequence in order to facilitate

cloning (Table 1) To minimize PCR errors, a Hi-Fidelity

DNA polymerase (Hi-Fidelity-PCR Enzyme mix, Abgene)

was used The amplified hpdA and hpdB genes were cloned

into pBluescript II SK(+) (Stratagene) Three clones of

three individual PCR products were sequenced from

double-stranded DNA in order to obtain the type strain

sequences The hpdC gene was sequenced directly using the

PCR product as template

In order to allow an in-frame cloning of the individual

genes in expression vectors, mutagenic primers were used

to introduce suitable cleavage sites at the start codon and

downstream of the stop codon These primers were used to

amplify the desired gene from genomic DNA by PCR and

the fragments were inserted into pET11a, pET11d

(Nov-agen) or pASK-IBA7 vectors (Institut fu¨r Bioanalytik,

Go¨ttingen, Germany) The resulting clones were sequenced

on both strands and PCR artefacts were replaced with

corresponding DNA from other clones The resulting clones

were designated pET-D3 (hpdB), pET-A4 (hpdA),

pASK-A2 (hpdA) and pET-X1 (hpdC)

The vector for the coexpression of hpdB and hpdC

(pET-DX4) was obtained from a PCR of genomic DNA using

the primers sDecNheI and InterCterBamHI (Table 1) The

fragment was cloned in pET11a vector and DNA without

mutations in the 3¢-end of hpdB and the entire hpdC gene

was used to replace a StuI/BamHI fragment in pET-D3

Production of HpdB and HpdC inE coli

The expression plasmids were used to transform several

E coli host strains including DH5a [8] GM2159 [9],

BL21TM(DE3) Codon Plus-RIL (Stratagene), TunerTM

(DE3)pLysS and RosettaTM(DE3)pLysS (Novagen) The growth conditions (media, temperature, oxygen) and the concentration of the inducers were varied in order to establish optimal conditions for the production of soluble proteins

HpdB/C and HpdC were produced by E coli BL21TM

(DE3) Codon Plus-RIL harbouring pET-DX4 and pET-X1 plasmids, respectively The cells were grown aerobically in

LB medium supplemented with glucose (0.2%), carbenicil-lin (100 lgÆmL)1) and chloramphenicol (50 lgÆmL)1) at 28–30
C (pET-DX4) and 37
C (pET-X1) Isopropyl thio-b-D-galactoside was added (1 mM) at D578of 0.5–0.8 After 3 h the cells were collected by centrifugation and stored frozen at)20
C

Purification of HpdB and HpdB/C All purification steps were performed in an anoxic chamber (Coy Laboratories, Ann Arbor, MI, USA) in a N2/H2

(95%/5%) atmosphere at 15–20
C

Hpd was purified from freshly prepared cells of C diff-icile(2–2.5 g) essentially as described previously [7] How-ever, the DEAE-Sepharose column used in the earlier preparations was omitted and the Resource-Q column was replaced by a Source 15Q (1.6/20 cm) column

The HpdB/C complex was purified from aerobically induced E coli BL21TM(DE3) Codon Plus-RIL/pET-DX4 The cell pellet (3.0 g) was washed with buffer A [100 mM

Tris/HCl pH 7.5, 5 mM(NH4)2SO4, 1 mMMgCl2, 0.5 mM

sodium dithionite, 20 lMATP] and resuspended in 25 mL uffer A The cell suspension was sonicated at 50 W, for

4· 5 min with a Branson sonifier (Branson Ultrasonics, Danbury, CT, USA) on ice Cell debris and membranes were removed by centrifugation (100 000 g, 60 min) The supernatant was loaded on a Resource-Q column (6 mL), which was equilibrated with buffer A The decarboxylase complex was eluted in a linear gradient of 0–450 mMNaCl

in 120 mL buffer A The fractions containing HpdB/C were concentrated using a Vivapure device with a 100 kDa cut-off membrane (Vivascience, Germany) and loaded on a prepacked Superdex 200 HR 10/30 gel filtration column The column was run in 150 mM NaCl in buffer A The elution and purity of the proteins were monitored by

Table 1 Amplification primers s, Sense-strand; as, antisense-strand.

SDS/PAGE with Coomassie blue staining and the purified

enzyme was stored anaerobically at 4
C

Production of HpdA

HpdA was produced anaerobically by E coli GM 2159

harbouring the pASK-A2 plasmid in LB medium

supple-mented with 0.2% glucose and carbenicillin (100 lgÆmL)1)

at 30
C The production of HpdA was induced at D

(578nm) of 0.35–0.5 with anhydrotetracycline (50 lgÆL)1)

for 20 h During the first 6 h of induction, the pH was

maintained at 7.5 by addition of 10MNaOH Cells were

harvested and the protein was immediately purified

Purification of recombinant HpdA

HpdA was purified in an anoxic chamber using 5 mL

StrepTactin Sepharose columns Wet packed cells (3.5–

5.0 g) were suspended in buffer B (20 mL) containing

100 mM Tris/HCl pH 8, 150 mM NaCl, 5 mM

dithiothre-itol, and homogenized by sonication Cell debris was

removed by centrifugation (60 min at 100 000 g) The clear

supernatant was applied onto the column equilibrated with

buffer B Non-bound protein was washed off with buffer B

prior to elution of HpdA with desthiobiotin (2.5 mM) in

buffer B The enzyme was concentrated in 2 mL Vivaspin

centrifugation devices with a cut-off of 10 kDa (final

concentrations > 1 mgÆmL)1) and stored anoxically at

)20
C

Reconstitution of the Hpd activityin vitro

All reconstitution steps were carried out under strict anoxic

conditions The recombinant HpdB/C was tested for

catalytic competence using endogenous HpdA in cell-free

extracts of C difficile Therefore, cell-free extracts from

C difficileand E coli Bl21TM(DE3) Codon

Plus-RIL/pET-DX4 (85 lgÆmL)1 and 28 lgÆmL)1 total protein,

respect-ively) were incubated at 30
C in 100 mMTris/HCl pH 7.5,

5 mM(NH4)2SO4, 1 mMMgCl2, 0.5 mMsodium dithionite,

with 20 mMp-hydroxyphenylacetate and 0.23 mM

S-aden-osyl-methionine (SAM) At defined time points samples

were withdrawn and analysed for p-cresol formation as

described previously [7] Controls omitting any of the

essential components (HpdA, HpdB/C or SAM) were

analysed in parallel assays

p-Hpd activity was also reconstituted with purified

recombinant proteins Pure HpdA (3.8 lg) was reduced

for 3 h in the presence of 0.5 mM sodium dithionite,

0.57 mM SAM and 17 lg HpdB/C in a final volume of

100 lL 100 mMTris/HCl pH 7.5, 5 mM(NH4)2SO4, 5 mM

dithiothreitol, 1 mM MgCl2 (100 lL) at 4
C To follow

the decarboxylation, 25 mM substrate (1 mL) was added

Aliquots were taken at defined time points and assayed for

p-cresol formation by HPLC as described previously [7]

MALDI-TOF MS of HpdC

Partially purified decarboxylase from C difficile and

recom-binant HpdB/C were acidified with trifluoroacetic acid

(TFA) The supernatant was subjected to solid phase

extraction using 50 mg-Sep-Pak Vac C18-cartridges

(Waters) equilibrated with 0.1% TFA The columns were washed twice with 1 mL 0.1% TFA and eluted with 0.1% TFA/67% acetonitrile The samples thus obtained (1 lL) were mixed on a gold-plated target with 1 lL of a saturated solution of sinapinic acid in 0.1% TFA/67% acetonitrile and dried under air The samples were analysed using a Voyager-DE/RP-MALDI-TOF MS in reflector mode

Determination of relative molecular masses

of the native enzymes The apparent molecular masses of the native 4-Hpd was determined by gel filtration on a Superdex 200 HR 10/30 prepacked column, equilibrated with 150 mM NaCl in buffer A Ribonuclease A from bovine pancreas (13.7 kDa), chymotrypsinogen A from bovine pancreas (27 kDa), ovalbumin from hen egg (43 kDa), albumin from bovine serum (67 kDa), aldolase from rabbit muscle (158 kDa), ferritin from horse spleen (440 kDa) and thyroglobulin from bovine thyroid (669 kDa) were used as molecular mass marker proteins (Amersham Biosciences, Germany.) Other methods

Protein concentrations were determined using the Bradford procedure [10]

Results

Based on the N-terminal amino acid sequence of purified HpdB, a putative operon was identified in the genome of

C difficilestrain 630, which encoded both the glycyl radical subunit of the decarboxylase (HpdB) and its activating enzyme (HpdA) A detailed analysis of the sequence taking into account putative ribosome binding sites (RBS) estab-lished a third ORF (hpdC) located between hpdB and hpdA(Fig 1) During the initial purification of the decar-boxylase from C difficile this small protein (85 amino acids, 9.5 kDa) was overlooked However, the low activity yield of the purification was attributed to the loss of a low molecular mass cofactor [6,7]

Based on the genomic DNA sequence of C difficile strain

630, specific primers were deduced in order to amplify the genes encoding the two putative decarboxylase subunits and its activase by PCR from genomic DNA of the type strain DSM 1296T The type strain sequences have been deposited

in the EMBL Nucleotide Sequence Database under the accession numbers AJ543425 (hpdB), AJ543426 (hpdC) and AJ543427 (hpdA) Within the hpdB gene, nine nucleotides were exchanged between the type strain and strain 630, but only two of these replacements changed the amino acid sequence (M670I and E806D) The gene of the small subunit (hpdC) contained two exchanged nucleotides, which were silent at the amino acid level In hpdA, one nucleotide differed, leading to one amino acid exchange (I165V) The recombinant proteins were produced in E coli from inducible expression vectors Suitable endonuclease cleavage sites were introduced by PCR mutagenesis in order to allow in-frame cloning of the genes While the BamHI sites introduced in the 3¢-UTR of the genes did not affect the resulting amino acid sequences, the introduction of NheI or NcoI sites next to the start codon altered the N-terminal

sequences of the resulting proteins (MSQS to MASS in

HpdB, MRKH to MGKH in HpdC and MSSQ to MASQ

in HpdA) In contrast with the hpdC gene product, which

was produced in a variety of host cells as a soluble protein,

HpdB and HpdA were synthesized only in RosettaTM

(DE3)pLysS and BL21TM(DE3) Codon Plus-RIL cells

These hosts produce additional rare tRNAs and therefore

support the expression of AT-rich genes such as hpdA and

hpdB Although strongly induced by isopropyl

thio-b-D-galactoside, the proteins were produced as inclusion

bodies Neither variations in induction procedure nor media

nor temperature yielded soluble protein (data not shown)

The coexpression of hpdB and hpdC was achieved from

a pET11a-derived expression clone, which contained both

genes In order to obtain this clone, the 3¢-region of hpdB

and the hpdC gene were introduced into the existing clone of

hpdB in pET11a The resulting plasmid contained the

vector-derived RBS and 5¢-UTR in front of the hpdB gene

but the clostridial RBS and 5¢-UTR in front of hpdC

Expression of this construct in E coli BL21TM (DE3)

Codon Plus-RIL was efficient for both polypeptides and

resulted in soluble protein

Though no formation of p-cresol was observed in cell-free

extracts from E coli coexpressing hpdB and hpdC, a

catalytically competent protein was produced As shown

in Fig 2, the decarboxylase was rapidly activated by HpdA

from cell-free extracts of C difficile yielding a specific activity of 90 mUÆmg)1corrected for an almost negligible background activity of the C difficile extract, demonstra-ting the production of a functional recombinant enzyme While strict anoxic conditions were required to achieve activation, the process was equally effective for cell-free extracts containing HpdB/C prepared from aerobically or anaerobically grown cells No p-cresol formation was detected in the Resource-Q fractions containing separated subunits HpdB or HpdC These results show that HpdC is essential for p-cresol formation and establish this polypep-tide as a subunit of p-Hpd

The decarboxylase was originally purified from cell-free extracts of C difficile by successive anion exchange chro-matography on DEAE-Sepharose and Resource-Q fol-lowed by size exclusion chromatography on Superdex 200 [7] The DEAE Sepharose column led to a loss of 95% of the activity and was therefore omitted throughout this work without significantly affecting purity The presence of both HpdB and HpdC in these preparations was demonstrated both on SDS/PAGE and by MALDI-TOF MS (see below) and < 10% of the initial activity was lost in the first step Gel filtration, however, led to a separation of the subunits and the final activities were found to be similar to those reported previously (< 0.5 UÆmg)1)

The recombinant decarboxylase eluted from the anion exchange column in a similar position to the enzyme from

C difficile In contrast, the behaviour of this enzyme on the size exclusion chromatography column was surprisingly different: The nonactivated homo-dimeric decarboxylase (eluting at
15 mL) was found only in poor yields and essentially free of HpdC (Fig 3) The majority of the recombinant decarboxylase eluted at
12 mL, indicating

a native molecular mass of 460 kDa As judged by SDS/ PAGE, this protein was composed of HpdB and HpdC polypeptides The relative intensities of the bands were estimated by scanning and quantified using the Molecular DynamicIMAGEQUANT5.2 program The ratio of HpdB(b)/ HpdC(c) was corrected for the different sizes and found

to be 1 : 1, indicating an b4c4 composition in a hetero-octameric complex

Both the protein preparations from C difficile and the recombinant ones were analysed by MALDI-TOF MS Since the fully purified enzyme from C difficile was essentially free of HpdC, partially purified enzyme obtained from Source 15Q anion exchange column was subject

to a solid phase extraction procedure The molecular mass observed for HpdC in these preparations was

Fig 2 Activation of the recombinant HpdB/C complex Cell-free

extract from C difficile (85 lgÆmL)1) was incubated at 30
C in the

presence of 20 m M pHPA, in the absence (d) or presence (s) of

0.23 m M SAM In the presence of E coli extract containing HpdB/C

(n), a rapid activation of the recombinant decarboxylase was

observed The activation was strictly dependent on the endogenous

HpdA from C difficile and SAM (data not shown).

Fig 1 Location of the hpdC gene Potential clostridial ribosomal binding sites are boxed and the start codons are shaded grey The amino acid sequence of HpdC is shown in bold letters together with the C-terminal end

of HpdB and the N-terminal of HpdA.

9508 ± 9 Da This value is in good agreement with the

predicted molecular mass of 9504 Da for HpdC The mass

spectrum of recombinant HpdC was strikingly different:

in addition to a signal indicating a molecular mass of

9510 ± 9 Da, a second signal with equal intensity was

observed at 9590 ± 9 Da The 80-Da mass increment

between the two signals suggests a possible phosphorylation

of the small subunit in this enzyme, which could account for

the different oligomeric states

The recombinant activase was produced as an

N-terminally streptavidin-tagged protein and purified to

apparent homogeneity by affinity chromatography on

StrepTactin Sepharose under strict anoxic conditions

(Fig 4) The final preparation was deep brown, indicating

the expected presence of iron–sulfur clusters in the enzyme

Size exclusion chromatography showed HpdA to be a

monomeric enzyme that was determined to contain 7–8 mol

of iron and 6–7 mol of acid labile sulfur per mol of enzyme

The E coli extracts containing the recombinant activator catalytically activated the recombinant decarboxylase to yield specific activities of > 7 UÆmg)1 However, after purification of the recombinant enzymes, the efficiency of the activating process dropped dramatically yielding specific activities of below 1.5 UÆmg)1 This level of activity was achieved only with a large molecular excess of the activating enzyme (HpdA/HpdB/C¼ 10 : 1)

Discussion

Initial attempts to purify p-Hpd from C difficile [6] were unsuccessful Later, the decarboxylase was isola-ted) though almost inactive ) as a homodimer of the HpdB subunits [7] In both cases it was suggested that the low activity yield was due to the loss of a low molecular mass fraction of < 10 kDa during the purification

A closer analysis of the DNA sequence provided by the Sanger Center, taking into account the possible ribosomal binding sites, showed a third ORF, hpdC, located between the decarboxylase and the activase genes The hpdC gene starts directly downstream of the decarboxylase gene (hpdB), and overlaps the 5¢-region of hpdA It encodes an 85-amino acid, cysteine rich polypeptide (9.4% cysteine) In contrast with the well-studied glycyl radical enzymes pyruvate formate-lyase and class III ribonucleotide reductase, which are homodimeric enzymes (for review see [11,12]), the findings reported in this paper suggest a hetero-oligomeric structure of the decarboxylase in the catalytically competent enzyme A hetero-oligomeric structure has been described for the benzylsuccinate synthase of Thauera aromatica and related organisms [13,14] Whereas the small subunits form

a stable complex with the glycyl radical subunit in benzyl-succinate synthase and therefore copurify, the complex of HpdB and HpdC is apparently much weaker and rapidly dissociates during the purification

The first evidence for an important structural function of HpdC in the decarboxylase arose from the observation that HpdB produced by E coli/pET-D3 exclusively yielded insoluble protein, whereas coexpression of hpdB and hpdC gave a soluble, catalytically competent enzyme, which was smoothly activated by cell-free extracts of C difficile

An important, probably regulatory function of HpdC became evident during the purification of the recombinant protein The molecular mass data immediately suggested a phosphorylation of HpdC, which could affect the oligo-meric structure and complex stability of the decarboxylase Since recombinant HpdC is not phosphorylated when produced by E coli/pET-X1 plasmid (data not shown), it seems very likely that its phosphorylation is a catalytic property of the HpdB subunit Indeed, a Prosite motif scan

of the HpdB amino acid sequence revealed the presence of a P-loop ATP-binding motif (PS00017, [AG]-x(4)-G-K-[ST]) comprising amino acids 181–188 (AKEWVGKS) [15] However, at present it is not possible to exclude an artificial origin for this modification in E coli and further analysis of this putative phosphorylation will be required in order to establish its functional relevance

A correlation between glycyl radical concentration and Ævolume activity for partially purified enzyme from C diff-icile, containing the HpdC subunit, allowed an estimate for the specific activity of about 50 UÆmg)1in a fully active

Fig 4 Purification of HpdA from E coli cells expressing Strep-tagged

hpdA The samples were separated by SDS/PAGE and stained with

Coomassie blue Cell-free extracts of noninduced cells (NI), induced

cells (I) and the affinity purified product (HpdA) are shown

(S: standard proteins).

Fig 3 Purification of HpdB/C from E coli coexpressing hpdB and

hpdC The SDS/PAGE analysis of an elution profile from a Superdex

200 column is shown Consecutive fractions of the 450-kDa (15–17)

and the 200-kDa (24–27) region were analysed by SDS/PAGE and

Coomassie blue staining Cell-free extracts of noninduced (NI) and

induced (I) cells and partially purified enzyme from the Resource-Q

column (R) are shown for comparison Molecular masses of standard

proteins (S) and the positions of HpdB and HpdC are indicated.

decarboxylase with one radical site per HpdB dimer The

recombinant, octameric complex of HpdB and HpdC is

smoothly activated using either endogenous HpdA from

C difficile extracts or recombinant HpdA from E coli

extracts The specific activity of the recombinant

decarb-oxylase is higher (7 UÆmg)1) than the highest activity

observed for the homo-dimeric enzyme purified from

C difficile (< 0.5 UÆmg)1), but is still significantly lower

than the estimated maximum value These findings suggest

that the recombinant decarboxylase and the recombinant

activating enzyme are functional; however, the

reconstitu-tion of the system using individually purified enzymes

in vitrois difficult due to an essential requirement for an as

yet unknown factor present in the cell extracts of both

C difficileand E coli Apparently, this factor is lost during

purification and limiting when cell-free extracts are used to

restore activity (P I Andrei and M Blaser, unpublished

data), suggesting that higher specific activities might be

obtained by providing the missing compound

Interestingly, a small fraction of the recombinant

decarb-oxylase dissociated during the purification While the

resulting homo-dimers of nonactivated HpdB thus obtained

remained soluble and have been purified, all attempts to

detect activity in these preparations failed It will be

interesting to establish whether the glycyl radical formation

by HpdA is possible with this form or whether it inhibits this

reaction with the functional complex

The function of HpdC remains to be established, but the

data presented strongly suggest that this small subunit is

essential for catalytic activity and may play an important role

in regulation of the decarboxylase system Indeed, the

presence of this small subunit distinguishes the 4-Hpd from

all other groups of glycyl radical enzymes While several

hundreds of putative glycyl radical enzymes are found in the

finished and unfinished genomes of microbes, only one

additional putative arylacetate decarboxylase has been found

so far in the unfinished genome of the human pathogen

Tannerella forsythensis ATCC 43037 (formerly named

Bacteroides forsythus), the sequence for which can be

obtained from http://tigrblast.tigr.org/ufmg/index.cgi?data

base¼ b_forsythus The gene encoded amino acid

sequence of a putative glycyl radical enzyme of this organism

is highly similar (57% identity, 88% similarity) to HpdB and

also has a small ORF encoding an 86-amino acid protein

directly downstream The amino acid sequence of this small

protein is 33% identical and 58% similar to HpdC Since

T forsythensishas very complex growth requirements and is

therefore not accessible for metabolic testing in vivo,

recom-binant production of this enzyme will be performed in order

to study the properties of this new system and to compare its

properties with those of the Hpd from C difficile

Acknowledgements

We are very grateful to Prof Dr W Buckel for his constant support

throughout the project and to Dr Dan Darley for proof-reading the

manuscript We also like to thank the Max-Planck Institute for Terrestrial Microbiology for the access to MALDI-TOF MS and EPR This work was supported by grants from the priority program Radicals

in Enzymatic Catalysis of the Deutsche Forschungsgemeinschaft (DFG) and is dedicated to Prof Dr Achim Kro¨ger Prof Dr Kro¨ger was a member of the reviewing panel of the priority program and died

on 11 June 2002.

References

1 Spencer, R.C (1998) Clinical impact and associated costs of Clostridium difficile-associated disease J Antimicrob Chemother Suppl C41, 5–12.

2 Fedorko, D.P., Engler, H.D., O’Shaughnessy, E.M., Williams, E.C., Reichelderfer, C.J & Smith, W.I Jr (1999) Evaluation of two rapid assays for detection of Clostridium difficile toxin A in stool specimens J Clin Microbiol 37, 3044–3047.

3 Borriello, S.P & Wilcox, M.H (1998) Clostridium difficile infec-tions of the gut: the unanswered quesinfec-tions J Antimicrob Chemother Suppl C41, 67–69.

4 Elsden, S.R.H.M.G & Waller, J.M (1976) The end products of the methabolism of aromatic amino acids by Clostridia Arch Microbiol 107, 283–288.

5 Hafiz, S & Oakley, C.L (1976) Clostridium difficile: isolation and characteristics J Med Microbiol 9, 129–136.

6 D’Ari, L & Barker, H.A (1985) p-Cresol formation by cell-free extracts of Clostridium difficile Arch Microbiol 143, 311–312.

7 Selmer, T & Andrei, P.I (2001) p-Hydroxyphenylacetate decarboxylase from Clostridium difficile A novel glycyl radical enzyme catalysing the formation of p-cresol Eur J Biochem 268, 1363–1372.

8 Sambrook, J & Russell, D.W (1989) Molecular cloning.

A laboratory Manual, 3 edn, Cold spring harbor laboratory press, New York.

9 Parker, B & Marinus, M.G (1988) A simple and rapid method to obtain substitution mutations in Escherichia coli: Isolation of a dam deletion/insertion mutation Gene 73, 531–535.

10 Bradford, M.M (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding Anal Biochem 72, 248–254.

11 Fontecave, M (1998) Ribonucleotide reductases and radical reactions Cell Mol Life Sci 54, 684–695.

12 Sawers, G & Watson, G (1998) A glycyl radical solution: oxygen-dependent interconversion of pyruvate formate-lyase Mol Microbiol 29, 945–954.

13 Coschigano, P.W., Wehrman, T.S & Young, L.Y (1998) Identi-fication and analysis of genes involved in anaerobic toluene metabolism by strain T1: putative role of a glycine free radical Appl Environ Microbiol 64, 1650–1656.

14 Leuthner, B., Leutwein, C., Schulz, H., Horth, P., Haehnel, W., Schiltz, E., Schagger, H & Heider, J (1998) Biochemical and genetic characterization of benzylsuccinate synthase from Thauera aromatica: a new glycyl radical enzyme catalysing the first step in anaerobic toluene metabolism Mol Microbiol 28, 615–628.

15 Walker, J.E., Saraste, M., Runswick, M.J & Gay, N.J (1982) Distantly related sequences in the alpha- and beta-subunits of ATP synthase, myosin, kinases and other ATP-requiring enzymes and a common nucleotide binding fold EMBO J 1, 945–951.