(Received for publication, August 21, 1996, and in revised form, December 20, 1996)
From the Institut für Pharmakologie und Toxikologie der Albert-Ludwigs-Universität Freiburg, D-79104 Freiburg, Germany
Clostridium difficile toxin B that is one of the largest cytotoxins (270 kDa) known acts on Rho subfamily proteins by monoglucosylation (Just, I., Selzer, J., Wilm, M., von Eichel-Streiber, C., Mann, M., and Aktories, K. (1995) Nature 375, 500-503). By deletion analysis we identified the enzyme and cytotoxic activity of the toxin to be located at the N terminus of the holotoxin. A 63-kDa fragment of toxin B covering the first 546 amino acid residues glucosylated Rho, Rac, and Cdc42, but not Ras, by using UDP-glucose as a cosubstrate. As known for the holotoxin, glucosylation by the toxin fragment was favored with the GDP-bound form of the low molecular mass GTPases. Microinjection of the toxin fragment into NIH-3T3 cells induced rounding up of cells and redistribution of the actin cytoskeleton. In contrast, a toxin fragment encompassing the first 516 amino acid residues was at least 1000-fold less active than toxin fragment 1-546 and cytotoxically inactive. The data give direct evidence for location of the enzyme activity of C. difficile toxin B at the N-terminal 546 amino acids residues and indicate a functionally and/or structurally important role of the region from amino acid residues 516 through 546 for enzyme and cytotoxic activities.
Clostridium difficile is suggested to be responsible for about 20% of cases of antibiotic-induced diarrhea and is presumably the most important pathogen for induction of pseudomembranous colitis associated with antibiotic therapy (1, 2). The major virulence factors of C. difficile are the enterotoxin A and the cytotoxin B (ToxB).1 Recently, it has been reported that the toxins are enzymes that covalently modify low molecular mass GTP-binding proteins of the Rho family by glucosylation (3-5). Using UDP-glucose as cosubstrate, the toxins specifically glucosylate Rho, Rac, and Cdc42 at threonine 37 and threonine 35, respectively, thereby inhibiting the biological activity of the small GTPases. Because Rho proteins are regulators of the actin cytoskeleton (6-8), glucosylation results in destruction of the cytoskeleton (3) and in inhibition of various signal transduction processes that are controlled by these GTPases (9).
Recently, the genes for C. difficile toxins were cloned and sequenced to show that they encode proteins of 308 and 270 kDa (10-12). From these data it has been proposed that the primary structures of these large toxins are characterized by three domains: the C-terminal part with repetitive oligopeptides suggested to be involved in receptor binding via glycoconjugates. The middle part has a rather small hydrophobic region and is tentatively assumed to be involved in membrane translocation (10, 12). Finally, it was speculated that the N terminus of the toxins including a putative nucleotide binding site bears the biological activity. This hypothesis was deduced from preliminary mutational studies showing that deletion of the C-terminal part or deletion of the middle part of ToxB reduced cytotoxicity but did not completely block the cytotoxic effects (13). However, no direct evidence for the location of cytotoxic activity at the N terminus has been presented. Because it is now clear that C. difficile toxins A and B are monoglucosyltransferases, we were prompted to localize their enzymatic activity to specific parts of the toxin molecule. Here we report that N-terminal fragments of ToxB that are expressed in Escherichia coli possess glucosyltransferase activity capable of modifying specifically small GTPases and cause potent cytotoxic effects after microinjection into culture cells.
UDP-[14C]hexoses were obtained from DuPont NEN (Dreieich, Germany). PCR primers were from Pharmacia (Freiburg, Germany). All other reagents were of analytical grade and purchased from commercial sources.
Purification of C. difficile ToxBA dialysis bag containing 900 ml of 0.9% NaCl in a total volume of 4 liters of brain heart infusion was inoculated with 100 ml of an overnight brain heart infusion culture of C. difficile strain VPI 10463. After incubation under microaerophilic conditions at 37 °C for 72 h, the culture was centrifuged at 8000 × g for 20 min in a Sorvall GSA rotor. Ammonium sulfate was slowly added to the cleared culture filtrate to a final concentration of 70%. After 3 h of mixing at 4 °C, the suspension was centrifuged at 8000 × g for 30 min at 4 °C. The precipitate formed was dissolved in 15 ml of 0.05 M Tris-HCl buffer (pH 7.5) and dialyzed overnight at 4 °C against 1 liter of the Tris buffer. The dialyzed sample was cleared by centrifugation (8000 × g for 30 min at 4 °C) and directly applied to a MonoQ column (HR 10/10; Pharmacia, Freiburg, Germany) previously equilibrated with 0.05 M Tris-HCl buffer (pH 7.5). Proteins were eluted by using a 0.05 to 0.7 M NaCl gradient. ToxB eluted at about 0.5 M NaCl as a single protein peak (>90% pure) and was identified by cytotoxicity.2
PCR AmplificationC. difficile strain VPI 10463 was used as the source for preparation of chromosomal DNA as described
previously (14). Amplification of the toxin fragments CDB1, CDB2, and
CDB3 was performed by PCR with the GeneAmp PCR System 2400 from
Perkin-Elmer using the primer pairs CDB1C/CDB1N
(5-AGATCTATGAGTTTAGTTAATAGAAAAC-3
/5
-GGATCCAAATCTTATACTAAATCCCT3
) for CDB1, CDB2C/CDB2N
(5
-AGATCTATTAATAAAGAAACTGGAGAAT-3
/5
-GGATCCAATAAAATCATTACCATCATT-3
) for CDB2, and CDB3C/CDB3N (5
-
AGATCTCTTATGTCAACTAGTGAAGA-3
/5
-GGATCCCTATTCACTAATCACTAATT-3
) for
CDB3, respectively.
Amplification was done with 300 nmol of primers, 250 ng of chromosomal DNA for 30 cycles (denaturation, 94 °C, 10 s; annealing, 48 °C, 30 s; elongation 68 °C, 3 min) in a total volume of 100 µl. The amplified DNA fragments were cleaved with BglII/BamHI and cloned in pGEX-2T (Pharmacia, Germany) expression vector.
C-terminal Truncation of CDB1Further C-terminal deletions of CDB1 were done by restriction enzyme cleavage with BsaBI/EcoRI for CDB1-546, NheI/EcoRI for CDB1-516, and AflII/SmaI for CDB1-468. Religation of the resulting truncated fragments was performed after treatment with DNA polymerase I, large (Klenow) fragment.
SequencingSequencing of CDB1 and all its truncated derivatives, CDB2, and CDB3 was done with the ABI PRISMTM dye terminator cycle sequencing ready reaction kit (Perkin-Elmer) to check both for correct cloning and mutations due to PCR amplification. Sequencing was performed at least twice with overlapping DNA fragments. Cycle sequencing revealed nucleotide exchanges in CDB1 at three positions, two of which resulted in amino acid exchanges (M substituted by I at position 1; Y substituted by C at position 55). These amino acid exchanges did not result in changes of enzyme activity.
Expression of Recombinant ProteinsThe recombinant GTP-binding proteins RhoA, Rac, Cdc42, and Ha-Ras were prepared from their fusion proteins as described previously (4). The recombinant toxin fragments were expressed and purified as GST fusion proteins in accordance with the manufacturer's instructions. GST fusion proteins from the E. coli expression vector pGEX-2T were isolated by affinity chromatography with glutathione-Sepharose (Pharmacia, Germany) followed by cleavage of the toxin fragment proteins from the GST fusion protein by thrombin treatment (100 µg/ml for 30 min at 22 °C). Removal of thrombin was achieved by binding to benzamidine-Sepharose.
Microinjection StudiesFor microinjection studies, NIH-3T3 cells were grown for 24 h in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum, 4 mM glutamine/penicillin/streptomycin and plated on Cellocate (Eppendorf, Germany) coverslips at about 105 cells/dish. Microinjection was performed with a Microinjector 5242 and Micromanipulator 5171 from Eppendorf. Actin cytoskeleton staining was performed with rhodamine-phalloidin after fixation of cells with paraformaldehyde (4%) plus Triton X-100 (0.2%).
Glucosylation ReactionRat brain tissue lysate (1 mg/ml) or recombinant GTP-binding proteins (30 µg/ml) were incubated with either ToxB (1 µg/ml) or recombinant toxin fragments (1-25 µg/ml) in a buffer containing 50 mM Hepes (pH 7.5), 100 mM KCl, 2 mM MgCl2, 100 µg/ml bovine serum albumin for 30 min at 37 °C. The total volume was 20 µl. For sequential glucosylation, GST-RhoA (1 µg) was glucosylated with either ToxB or CDB1 in the presence of unlabeled UDP-glucose (1.5 mM) for 30 min at 37 °C and washed three times. Thereafter, a second glucosylation in the presence of UDP-[14C]glucose (10 µM) and CDB1 (10 µg/ml) or ToxB (10 µg/ml) was performed for 10 min at 37 °C. Labeled proteins were analyzed by SDS-PAGE and subsequently by phosphorimaging (Molecular Dynamics, Inc.). For studies on the nucleotide dependence of glucosylation, RhoA was incubated for 15 min at room temperature in a buffer containing 150 mM NaCl, 50 mM Tris (pH 7.5), 2.5 mM Ca2+, 5 mM EDTA, 2.5 mM GDP or 2.5 mM GTP. Thereafter, MgCl2 was added to give 7 mM. Then, nucleotide-loaded Rho was glucosylated as described above.
To identify functional domains of the C. difficile
toxin B, we first split the structural gene encoding the toxin B into
three parts (CDB1, CDB2, CDB3) of almost similar length and engineered these fragments into an E. coli expression vector as
described under "Experimental Procedures" (see also Fig.
1). As shown in Fig. 2A, the
N-terminal part of ToxB (fragment CDB1) was able to glucosylate Rho
subtype proteins in lysates of rat brain tissue as efficiently as the
holotoxin. Deduced from previous studies, the upper band is most likely
Rho while the lower band is Rac and Cdc42 (15). In contrast, the
C-terminal part (CDB3) and the middle fragment (CDB2) of ToxB were
without activity. To study whether the N-terminal fragment of ToxB
modifies the same amino acid as the holotoxin, we first treated
recombinant GST-Rho beads with the holotoxin or with fragment CDB1 in
the presence of unlabeled UDP-glucose. Thereafter, the GST-Rho beads
were washed and a second glucosylation was initiated by addition of
either holotoxin or CDB1 plus labeled UDP-[14C]glucose.
As shown in Fig. 2B, pretreatment of Rho with the holotoxin or with CDB1 prevented the second glucosylation reaction indicating that both the holotoxin and the toxin fragment modified the same amino
acid residue (e.g. threonine 37 of Rho).
Recently, it has been proposed that the region from amino acid residue
651 through 683 plays a pivotal role in cytotoxicity of ToxB (13). This
region was suggested to be involved in nucleotide binding. Therefore,
we studied the effects of deletion of this region on enzyme activity of
fragment CDB1 of ToxB. We engineered a toxin fragment encompassing the
first 546 amino acid residues but missing the proposed
nucleotide-binding region (see Figs. 1 and 3). This
toxin fragment (CDB1-546) was still able to glucosylate Rho proteins
(Fig. 4). It was even more active than the holotoxin. At
present we cannot conclude that the deletion activates ToxB because the
difference in activity was rather small and the holotoxin and the toxin
fragment were prepared by completely different procedures. When the
active toxin fragment CDB1-546 was further deleted by 30 amino acid
residues at the C terminus (Figs. 1 and 3), glucosyltransferase activity was dramatically decreased (Fig. 4). In the presence of Rho as
substrate practically no glucosylation occurred (Fig. 4B).
With Rac as substrate, a minor glucosylation was observed (Fig.
4A). However, the activity of CDB1-516 was more than
1000-fold less than the activity of CDB1-546. Further deletion
resulting in a fragment of 468 amino acids (CDB1-468) caused complete
loss of activity.
Similar to what was found with the holotoxin, the CDB1-546 fragment
glucosylated Rho, Rac, and Cdc42 but not Ras proteins (Fig.
5A). Moreover, the cosubstrate specificity
was the same as reported recently for the holotoxin (3). Thus, only
UDP-glucose but not other activated monosaccharides such as
UDP-galactose or UDP-N-acetylglucosamine were accepted as
cosubstrates for modification of native Rho proteins in brain tissue
lysates (Fig. 5B) or recombinant Rho proteins (not shown).
Recently, it was reported that the GDP bound form of Rho proteins is
the favored substrate for glucosylation by ToxB (3). In line with this
report, we observed that the active toxin fragments (CDB1 and
CDB1-546) glucosylated Rho in the GDP-bound form to a higher extent
than in the GTP-bound form (Table I).
|
Next we tested the biological activity of the toxin fragments by
microinjection studies. For this purpose, the CDB1 fragment of C. difficile ToxB was microinjected into NIH-3T3 cells. About 30 min
after microinjection into NIH-3T3 cells, morphological changes
occurred. The cells rounded up in a manner typical for the action of
C. difficile ToxB (Fig. 6). As shown by the
rhodamine-phalloidin staining of the actin cytoskeleton (Fig. 6), the
toxin fragment caused destruction of the actin microfilaments as
observed after treatment of cells with the holotoxin. These cytotoxic
effects were not detected after microinjection of the C-terminal part (CDB3) or the middle part (CDB2) of the toxin. Moreover, the same changes in cell morphology and destruction of the actin cytoskeleton were observed with the 63-kDa fragment CDB1-546 of ToxB (not shown) indicating that after microinjection this small N-terminal toxin fragment encompasses the cytotoxicity of the 270-kDa holotoxin.
Here we present direct evidence that the N-terminal part (amino acid residues 1-546) of C. difficile toxin B bears the enzyme activity of the holotoxin. Only in the presence of the N-terminal fragment, but not with the middle or C-terminal fragment of the toxin, were Rho subfamily proteins glucosylated. Glucosylation of Rho proteins by N-terminal toxin fragments exhibits the same biochemical characterization as glucosylation catalyzed by the holotoxin. First, the protein substrate specificity of the constructed N-terminal fragments (CDB1, CDB1-546) and of the holotoxin are the same showing modification of Rho subfamily proteins (Rho, Rac, Cdc42) but not of Ras. Second, modification of Rho by the toxin fragments occurs most likely at Thr-37 of Rho, because pretreatment with the holotoxin inhibits subsequent modification by fragment CDB1 and, conversely, glucosylation by CDB1 blocks subsequent modification by the holotoxin. Third, the GDP-bound form of the GTPase is the preferred substrate for glucosylation. The latter finding has been recently explained by conformational changes of Rho occurring upon GDP/GTP-binding. As deduced from the structure of Ras (16), in its GDP bound form, the hydroxyl group of Thr-37 is likely to be directed to the solvent and, therefore, accessible for glucosylation by the toxin. Finally, the cosubstrate of the toxin fragments CDB1 or CDB1-546 is UDP-glucose but not other activated monosaccharides. Thus, the N-terminal fragments of the C. difficile toxin B share the same enzymatic properties as the holotoxin. Further evidence for location of the biological activity of ToxB in the N-terminal part of the molecule is provided by microinjection studies. We show that the N-terminal part of the protein is responsible for the morphological changes caused by the holotoxin. These findings are also in line with recent reports that glucosylated Rho proteins per se are sufficient to induce cytotoxic effects (3).
Studies from past years indicate that bacterial toxins acting inside
cells are constructed of three major domains (17-19), a cell surface
binding site, a domain involved in membrane translocation, and a third
part responsible for the biological activity. Accordingly, it has been
suggested that the C terminus of C. difficile toxins, which
is characterized by several repeating sequences, is involved in binding
to the eukaryotic target cells (10, 12). The middle part of the toxins
containing a hydrophobic region with putative membrane spanning regions
was tentatively implicated in membrane translocation (20), and the
N-terminal part was suggested to harbor the cytotoxic activity (13,
20). Our findings unequivocally locate the biological activity of the
C. difficile toxins to the N terminus. Moreover, our studies
largely extend our knowledge about the structure-activity relationship
of ToxB. It has been proposed that a putative nucleotide binding region
(amino acid residues 651-683) located in the N-terminal part of the
toxin is essential for cytotoxicity (13). A change of His-653 to Glu reduced the cytotoxic action at least 100-fold (13). Here we show that
this region is not essential for the glucosylation of Rho subfamily
proteins and for induction of cytotoxic effects, because fragment
CDB1-546 (amino acid residues 1-546), showing the same enzymatic and
cytotoxic activities as the holotoxin, does not contain this region.
Moreover, several cysteine residues highly conserved in C. difficile toxins have been suggested to be important for the
cytotoxic action of the holotoxin. All these conserved cysteine
residues were absent in the fragment CDB1-546, apparently without
affecting its glucosyltransferase and cytotoxic activities. Thus, these
cysteine residues are not crucial for the enzyme activity of ToxB, but
may play a role in endocytosis or translocation of the toxin into the
cytosol. However, a toxin fragment encompassing amino acid residues
1-516 did show at least 1000-fold reduced glucosyltransferase
activity. Thus, the amino acid residues 517 through 546 appear to be
essential for enzyme activity and/or structure of ToxB. Taken together,
we show for the first time that the N-terminal part (546 amino acids)
of the C. difficile ToxB harbors the enzyme and cytotoxic
activities of the 270-kDa holotoxin. This finding will facilitate the
precise structure-function analysis of the family of large cytotoxins including C. difficile toxins A and B, the lethal and
hemorrhagic toxins of Clostridium sordellii, and the
-toxin of Clostridium novyi.
We thank B. Haag for excellent technical assistance.