Structure-Function Analysis of Invasion Plasmid Antigen C (IpaC) from Shigella flexneri*

Lisa A. KueltzoDagger §, John Osiecki§||, Jeff Barker||**, Wendy L. Picking||, Baran ErsoyDagger , William D. Picking||DaggerDagger, and C. Russell MiddaughDagger

From the Departments of Dagger  Pharmaceutical Chemistry and || Molecular Biosciences, University of Kansas, Lawrence, Kansas 66045

Received for publication, August 16, 2002, and in revised form, November 7, 2002

    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Shigella flexneri causes a self-limiting gastroenteritis in humans, characterized by severe localized inflammation and ulceration of the colonic mucosa. Shigellosis most often targets young children in underdeveloped countries. Invasion plasmid antigen C (IpaC) has been identified as the primary effector protein for Shigella invasion of epithelial cells. Although an initial model of IpaC function has been developed, no detailed structural information is available that could assist in a better understanding of the molecular basis for its interactions with the host cytoskeleton and phospholipid membrane. We have therefore initiated structural studies of IpaC, IpaC I', (residues 101-363 deleted), and IpaC Delta H (residues 63-170 deleted). The secondary and tertiary structure of the protein was examined as a function of temperature, employing circular dichroism and high resolution derivative absorbance techniques. ANS (8-anilino-1-napthalene sulfonic acid) was used to probe the exposure of the hydrophobic surfaces under different conditions. The interaction of IpaC and these mutants with a liposome model (liposomes with entrapped fluorescein) was also examined. Domain III (residues 261-363) was studied using linker-scanning mutagenesis. It was shown that domain III contains periodic, sequence-dependent activity, suggesting helical structure in this section of the protein. In addition to these structural studies, investigation into the actin nucleation properties of IpaC was conducted, and actin nucleation by IpaC and some of the mutants was exhibited. Structure-function relationships of IpaC are discussed.

    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Shigella flexneri causes a self-limiting gastroenteritis called shigellosis, which is characterized by severe localized inflammation and ulceration of the colonic mucosa (1). An estimated 360,000 Shigella cases occur in the United States each year, although only 18,000 are reported (2). In developing countries, the disease is present in most villages. It most commonly strikes young children and is responsible for an estimated 600,000 deaths/year worldwide (all Shigella spp. combined) (1). Shigellosis onset involves bacterial invasion of intestinal epithelial cells by a process called "pathogen-induced phagocytosis" (2, 3) and requires the expression of the ipa operon. The invasion plasmid antigens (or Ipa1 proteins) are effector proteins that are exported by a dedicated type III secretion system (TTSS) at the host-pathogen interface. There they directly interact with the host cell to promote actin cytoskeleton rearrangements at the site of bacterial contact (2). These cytoskeletal changes give rise to filopodia, which mature into membrane ruffles that coalesce to trap the pathogen within a membrane-bound vacuole (2). The vacuole is then quickly lysed to provide the bacterium with access to the host cytoplasm, where it proliferates and is able to directly invade neighboring cells (4).

IpaC has been identified as the primary effector protein for Shigella invasion of epithelial cells (5-8). Effector-related functions described for purified IpaC include: (a) enhanced invasion of cultured cells by S. flexneri (5, 8, 9); (b) induced uptake of virulence plasmid-cured S. flexneri (5); (c) interaction with phospholipid membranes (9-11); and (d) triggering of cytoskeletal changes in cultured cells (7, 9, 12). Additional activities associated with IpaC include oligomerization in solution (8), reconstitution into complexes with IpaB in vitro (8), in vivo formation of complexes containing IpaB that promote the uptake of latex beads by cultured cells (6), and reconstitution with IpaB and IpaD to form a complex that may allow entry of noninvasive Escherichia coli into cultured cells (13).

It has been demonstrated that IpaC possesses a distinct functional organization (Scheme I). The immediate N terminus of IpaC is required for secretion, whereas a region near the N terminus is responsible for association with IpaB, which is probably needed for proper presentation of IpaC to the target cell membrane. The central hydrophobic region of IpaC directs IpaC penetration of phospholipid membranes and contributes to interactions with IpaB (14).2 The ability of IpaC to interact with phospholipid membranes does not require secretion by the TTSS of S. flexneri (Ref. 9 and this work); however, active insertion of IpaC into target cell membranes by the TTSS greatly increases the efficiency of this process (15). The C terminus of IpaC mediates IpaC-IpaC interactions and probably possesses IpaC effector function (7, 14). This information, however, only provides a very general picture of IpaC structure and function and its role in the S. flexneri infection process. Unfortunately, there exists no detailed structural information concerning IpaC that could provide a molecular basis for its interactions with the host cytoskeleton and phospholipid membranes.


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Scheme 1.   Functional organization of IpaC. The N terminus of IpaC harbors sequences for TTSS export and interaction with IpgC and IpaB. The central hydrophobic region is involved in IpaB binding, IpaC penetration of phospholipid membranes, and possibly protein stabilization. The C terminus possesses essential oligomerization and effector functions. Residues 101-363 are deleted in IpaC I' ,and residues 63-170 are deleted in IpaC Delta H.

In this work, we have initiated studies into the structure of IpaC by employing a number of biophysical approaches. Truncated versions of IpaC, specifically IpaC I' (residues 101-363 deleted) and IpaC Delta H (residues 63-170 deleted), were overexpressed in E. coli and purified, permitting structural analysis and a more comprehensive investigation into the role of the individual domains described above. The interaction of these mutants and full-length IpaC with a liposome model was also examined. In addition to these structural studies, an investigation into the actin nucleation properties of IpaC and these deletion constructs was conducted. Finally, domain III (residues 261-363), which has previously resisted attempts at purification after recombinant expression, was studied using an alternate technique, linker-scanning mutagenesis. From this, it is shown that domain III contains a sequence periodic structure-activity relationship, which suggests that the activity may be dependent on helical structure in this region. Interpretation of IpaC structure with regard to the functional properties of the wild-type protein is then discussed.

    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Materials-- DOPC (dioleoylphosphatidylcholine) and DOPG (dioleoylphosphatidylglycerol) were purchased from Avanti. ANS (8-anilino-1-naphthalene sulfonic acid) was obtained from Across Organics, and fluorescein (5,6-carboxyfluorescein, high purity) was obtained from Molecular Probes. Dialysis materials were provided by Spectra. All other chemicals were of reagent grade and obtained from Sigma and Fisher.

Preparation of Affinity-purified Recombinant Proteins-- Plasmids used to prepare recombinant IpaC and IpaC Delta H and sipC have been described previously (5, 16, 17). pWPI' was designed to encode an IpaC peptide called region I', in which residues 101-363 are deleted. This plasmid was generated as pWPC15 except that the 3' primer was designed to place a stop codon at amino acid 101. All new plasmids were transformed into E. coli BL21(DE3) for high level protein expression. Recombinant proteins were purified via the N-terminal His6 tag by nickel chelation chromatography under denaturing conditions as described in detail previously (5, 14, 17). Purified proteins were step-dialyzed against 10 mM NaPO4, pH 7.2, 150 mM NaCl containing 0.5 mM dithiothreitol to remove the urea.

Sample Preparation-- Purified proteins in buffer were stored at -70 °C for long term storage (IpaC only) or 4 °C for short term use (<2 weeks). All protein samples were centrifuged at 13,400 × g for 5 min at 4 °C on the day of use to remove aggregates formed during storage. Tween 20 (0.1%) was added to the IpaC solutions to further stabilize them during freezing. Unfortunately, neither centrifugation nor filtration was effective at completely removing all aggregated material (observed as a small amount of optical density above 300 nm in absorbance spectra). Concentrations were therefore obtained employing derivative absorbance spectroscopy, using N-acetyl-L-tyrosine-ethyl ester derivative minima at 275 and 283 nm to establish a standard curve since IpaC possesses no tryptophan residues. Biophysical studies were conducted in 10 mM NaPO4, 150 mM NaCl, pH 7.2, containing 1 mM dithiothreitol.

Circular Dichroism-- CD spectra were recorded with a Jasco J-720 spectrophotometer (Tokyo, Japan) equipped with a Peltier temperature controller. Far UV spectra (between 195 and 260 nm) were collected using a 1-mm path length cuvette sealed with a Teflon stopper. A resolution of 0.1 nm and a scanning speed of 20 nm/min with a 2-s response time were employed. Spectra presented are an average of six consecutive spectra. Spectra were recorded at 5 °C intervals employing a thermostated cuvette holder. An incubation time of 3 min at each temperature interval (sufficient for equilibrium to be obtained) and a temperature ramp rate of 20 °C/h were employed. Protein concentrations of 8.3, 26.3, and 11.2 µM were employed for IpaC, IpaC I', and IpaC Delta H, respectively. Noise reduction and data analysis were performed using Standard Analysis and Temperature/Wavelength Analysis programs (Jasco) and MicroCal OriginTM 6.0 software. Secondary structure content was estimated using the CONTIN (18), SELCON (19), and CDSSTR (20) analysis programs provided with the CDPro software suite (21).

Derivative Absorbance Spectroscopy-- High-resolution absorbance spectra were collected on a Hewlett-Packard 8453 UV-Visible spectrophotometer (Agilent, Palo Alto, CA) fitted with a Peltier temperature controller. Temperature perturbation studies were conducted at protein concentrations of 12.7, 25.3, and 16.9 µM for IpaC, IpaC I', and IpaC Delta H, respectively. Spectra were collected for 25 s at 2.5 °C intervals with a 3-min equilibration time before collection of each spectrum. Spectral analysis was conducted using UV-Visible Chemstation software (Agilent) and Microcal OriginTM 6.0. Second derivative spectra were calculated employing a nine-point data filter and fifth degree Savitzky-Golay polynomial and subsequently fitted to a cubic function with 99 interpolated points/raw data point, permitting 0.01-nm resolution (22). Peak positions were then determined from the interpolated curves. Optical density data were simultaneously monitored at 350 nm.

Lipid Interaction Studies-- Aliquots of DOPC and DOPG in chloroform were dried under nitrogen and vacuum to create thin films of either 100% DOPC or 50:50 [DOPC]:[DOPG]. Films were hydrated in a solution containing 100 mM 5,6-carboxyfluorescein at pH 7.0 in water for 10 min and then sonicated in a bath sonicator for 30 min prior to extrusion through a 100-nm pore size membrane 10 times at 45 °C. A final size of ~150 nm was determined with a Brookhaven ZetaPALS dynamic light scattering instrument (Holtsville, NY) equipped with a 25 mW 626-nm laser. Excess dye was separated from the bulk liposomes by size exclusion chromatography, employing a Sephadex G-25 column coupled to an AKTA FLPC (Amersham Biosciences). The run buffer was 10 mM NaPO4, 150 mM NaCl, pH 7.4. Peak fractions were collected and pooled, and lipid content was determined by a total phosphorous assay, as described (23). Solutions were stored at 4 °C and protected from light.

Time-based release studies were conducted with a PTI QuantaMaster spectrophotometer with a thermostated cuvette holder. Samples were excited at 492 nm, and the emission signal was monitored at 517 nm for 10 min. Excitation slits were set at 1 nm, and emission was set at 2 nm. Data points were collected at 0.2-s intervals. Data were collected as follows: buffer was incubated for 3 min at the desired temperature prior to adding liposome solutions. Baseline fluorescence was monitored with liposomes alone for 10 min to determine residual release of fluorescein from the liposomes. Maximum fluorescein release, as defined by release in the presence of 0.1% Triton, was determined by adding Triton to the liposome solution 3 min after the start of signal collection. Protein-induced fluorescein release was examined by monitoring the fluorescein signal at 512 nm after addition of protein to the liposome solution after 3 min of incubation. Both protein and Triton solutions were added during continuous signal collection through a syringe port in the sample compartment. The protein concentration employed was 1 µM, and the total lipid concentration was 100 µM. Release was monitored at 10, 20, 30, 35, 40, 45, 50, and 60 °C. Samples were measured in triplicate. The extent of release was calculated as a percentage of Triton-induced release at 600 s after background correction. Analysis was conducted using Felix (PTI) and MicroCal OriginTM software.

Assay for Actin Nucleation-- The fluorescence of pyrene-labeled G-actin monomers increases following assembly into pyrene F-actin (24). For monitoring IpaC-mediated actin nucleation in vitro, pyrene G-actin was incubated at 4 °C in G-actin buffer (5 mM Tris-HCl, pH 8.0, 0.1 mM ATP, 0.2 mM CaCl2). Test protein (IpaC or an IpaC mutant) was then added to the sample, and pyrene fluorescence was monitored at 23 °C. A Spex FluoroMax instrument (Jobin Yvon Horiba, Edison, NJ) was used to measure pyrene fluorescence using a time-based acquisition mode with an excitation wavelength of 330 and an emission wavelength of 385 nm. After 15 min, 50× actin polymerization buffer (100 mM MgCl2, 50 mM ATP, 2.5 M KCl) was added, and the change in pyrene fluorescence was monitored as a function of time. Negative controls either contained no added protein or contained IpaD, which has no actin-nucleating activity. SipC from Salmonella typhimurium, which has been shown to nucleate actin in vitro, was used as a positive control (24).

Linker-scanning Mutagenesis-- Linker-scanning mutagenesis was used to introduce consecutive site-specific mutations into a predicted coiled-coil segment near the C terminus of IpaC. Either NheI cleavage sites encoding Ala-Ser pairs or XhoI sites encoding Leu-Glu pairs were generated throughout the length of the putative coiled-coil region (amino acids 309-344). Primers with a 5' NheI or XhoI site and the appropriate neighboring ipaC sequences running in either direction were used for inverse PCR. The product was digested with NheI or XhoI, respectively, and then ligated. The resulting plasmids were electroporated into the S. flexneri IpaC mutant strain SF621, and the ability to restore invasion and contact hemolysis functions was determined as described below.

S. flexneri Invasion of Cultured Cells and Contact-mediated Hemolysis-- S. flexneri invasion of Henle 407 cells was monitored using a standard gentamycin protection assay as described (16). Semiconfluent monolayers of Henle 407 cells were seeded into 24-well plates and grown overnight. SF621 harboring the desired plasmid was grown in trypticase soy broth containing 100 µg/ml ampicillin and 50 µg/ml kanamycin to an A600 of 0.4-0.6. The bacteria were diluted with serum-free MEM containing 0.45% glucose (MEM-glc), centrifuged onto the surface of semiconfluent Henle 407 monolayers, and incubated with the cells for 30 min at 37 °C. Free bacteria were removed by aspiration, and the cells were washed with MEM containing 5% calf serum and 50 µg/ml gentamycin. The cells were incubated in the final gentamycin wash for 2 h (to kill adherent, noninternalized bacteria) and rinsed with MEM-glc. The cells were lysed by overlaying them with 250 µl of 0.5% agarose in water. The agarose was then overlaid with 0.5% agar containing 2× LB medium. After overnight incubation at 37 °C, internalized bacteria formed subsurface colonies that were quantified using a ChemiImager 4400 system (Alpha Innotech Corp., San Leandro, CA).

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Statistics-- All errors are reported as standard error (S.E., n = 3) unless otherwise indicated.

Spectroscopic Analysis of Full-length IpaC, IpaC I', and IpaC Delta H-- To better understand the function of IpaC in the S. flexneri invasion process, a series of structural studies were conducted to characterize the secondary and tertiary structure of full-length IpaC, IpaC I', and Delta H mutants and their response to temperature. All three proteins are efficiently secreted by the S. flexneri SF621 TTSS and are able to interact with IpaB, indicating that biological functions associated with the N terminus remain intact (14).

The CD spectrum of IpaC at 20 °C exhibits minima at 222 and 204 nm, suggesting the presence of some helical structure (Fig. 1A). Secondary structure estimates indicate that IpaC contains a mixture of alpha -helical and beta -sheet structure with significant turn and random structure also present (Table I). In contrast, IpaC I' and IpaC Delta H appear to be less structured, as indicated by a decrease in CD intensity above 210 nm. The spectrum of IpaC I' exhibits an increase in negative intensity near 200 nm, suggesting increased random structure. Solution conditions prevented collection of data below 200 nm, preventing secondary structure estimation for both mutants. IpaC undergoes a significant change in secondary structure at fairly moderate temperatures (Table I and Fig. 1). This transition suggests a loss of helix content (Table I) and has a midpoint of 43.3 ± 0.3 °C (n = 3). In contrast, IpaC I' and IpaC Delta H display evidence of only weak transitions between 10 and 40 °C. Although limited aggregation of some samples was observed above 30 °C, no red shifts or strong decreases in intensity indicative of absorption flattening were observed, indicating that the spectral changes are not an artifact of aggregation-dependent phenomena.


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Fig. 1.   Circular dichroism analysis of IpaC and its mutants. A, CD spectrum of IpaC and mutants at 20 °C. Protein concentrations were 8.3, 26.3, and 11.2 µM for IpaC, IpaC I', and IpaC Delta H, respectively. Spectra were collected at a rate of 20 nm/min employing a resolution of 2 nm. Spectra presented are an average of three consecutive spectra. The buffer used was 10 mM phosphate, 150 mM NaCl, and 1 mM dithiothreitol, pH 7.2. B-D, temperature dependence of the molar ellipticity at 222 nm of IpaC, IpaC I', and IpaC Delta H. A major loss in ellipticity is observed for the full-length IpaC with a Tm of 43.3 ± 0.3 (n = 3). Spectra were recorded at 5 °C intervals employing an incubation time of 3 min at each temperature interval and a temperature ramp rate of 20 °C/h. All other experimental conditions are as in panel A.

                              
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Table I
Secondary structure estimates for IpaC

Because IpaC lacks tryptophan residues, derivative absorbance spectroscopy was employed to monitor tertiary structure changes. This method is especially useful in aggregating systems since it is not sensitive to broad spectral components such as light scattering (25). The spectra display two phenylalanine (Fig. 2, A and B, 253 and 260 nm) and three tyrosine (Fig. 2, C-E, 268, 276, and 285 nm) minima (22). Most plots of peak position versus temperature show similar linear increases with temperature, which is an intrinsic property of the aromatic amino acids.3


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Fig. 2.   Wavelength of the derivative absorbance peaks of IpaC and mutants as a function of temperature. Second derivative absorbance minima arising from phenylalanine (A and B) and tyrosine (C-E) residues. IpaC (closed squares), IpaC I' (open circles), and IpaC Delta H (open triangles) are shown. F, expanded view of phenylalanine peak 2 position for IpaC I' showing a subtle deviation from linearity between ~30 and 60 °C. Protein concentrations were 12.7, 25.3, and 16.9 µM for IpaC, IpaC I', and IpaC Delta H, respectively. Spectra were collected for 25 s at 2.5 °C intervals with a 3-min equilibration time before collection of each spectrum. Error bars that are not visible are buried within the symbol.

However, deviations from these linear plots consistent with structural alterations are observed in many cases. The IpaC Phe minimum at 253 nm is shifted to longer wavelengths relative to the two mutants and shows no temperature dependence at lower temperatures. Upon reaching the temperature at which the protein begins aggregating, the noise in the data begins to increase. The second Phe minimum shows a difference in minimum position for each of the proteins with the IpaC peak once again at the longest wavelength. An expanded version of the IpaC I' data (Fig. 2F) shows that IpaC I' actually undergoes a small but very reproducible transition between 30 and 55 °C. The 267 nm IpaC I' tyrosine minimum is observed at longer wavelengths, disappearing from the derivative spectrum at temperatures above 62 °C. Two strong transitions are observed in the plot of the 276-nm tyrosine minimum of IpaC with no similar transitions seen for either mutant. The 284-nm IpaC I' and IpaC Delta H tyrosine minima again manifest no evidence of conformational change, whereas the IpaC absorption band shows evidence of the two transitions and is again present at a longer wavelength (Fig. 2E).

Trends in protein-associative behavior can be seen by monitoring the turbidity (OD) at 350 nm as the temperature is increased (Fig. 3). Full-length IpaC shows a large change in turbidity starting near 30 °C. Transitions are observed between 30 and 70 °C and above 70 °C. Although the changes are small, a distinct transition is observed starting at 55 °C for IpaC I', whereas IpaC Delta H shows a small but steady increase in OD starting at 20 °C (Fig. 3, bottom panels). Both results are consistent with the formation of soluble aggregates.


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Fig. 3.   Turbidity of ipaC and mutants as a function of temperature. Top, IpaC, IpaC I', and IpaC Delta H. WT, wild type. Bottom, expanded view of IpaC I' and IpaC Delta H. Experimental conditions are described in the legend for Fig. 2.

Full-length IpaC but Not the IpaC Mutants Interacts with Liposomes-- The effect of IpaC, IpaC I', and IpaC Delta H upon fluorescein-containing liposomes was examined as a function of the temperature and lipid composition. Fluorescein can be sequestered in liposomes at concentrations that produce self-quenching (26). Any interaction of a protein with such loaded liposomes that is sufficient to significantly perturb the bilayer should cause a leakage of the fluorescein, leading to its dilution and an increase in the fluorescence intensity of the fluorescein dye. Using this approach, two types of vesicles were employed: 100% DOPC, producing a neutral surface charge, and 50:50 [DOPC]:[DOPG] to produce an overall negatively charged surface.

The extent of dye release at 600 s at different temperatures is shown in Fig. 4. No release is observed for IpaC I' and IpaC Delta H. IpaC shows little release at low temperatures with DOPC liposomes, but a dramatic increase is observed at 30 °C and higher. Release at lower temperatures is greater with DOPC:DOPG liposomes. The rate of release is similar to that of the Triton control (results not illustrated). The liposomes remained above the phase transitions of the component lipids (-20 and -18 °C for DOPC and DOPG, respectively (27)) under all conditions examined.


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Fig. 4.   Release of fluorescein from liposomes after interaction with IpaC and mutants at various temperatures. Release is measured as percentage of maximum release in the presence of 0.1% Triton. Protein concentration was 1 µM for all cases, and total lipid concentration is 100 µM. Liposomes were comprised of 100% DOPC or a 50:50 molar mix of DOPC and DOPG.

Linker-scanning Mutagenesis Indicates That the IpaC C Terminus Is Important for Directing Uptake by Cultured Cells-- The region between amino acids 309 and 344 of IpaC is predicted to possess a coiled-coil trimerization domain based on primary structure analysis (28). Attempts to purify a recombinant form of this region have been unsuccessful, so a structural analysis of this region was conducted using linker-scanning mutagenesis. Initially, XhoI linkers were used to substitute Leu-Glu amino acid pairs for existing amino acids in this region of IpaC. Sequence periodicity in the generation of inactivating mutations with respect to restoring invasiveness to S. flexneri SF621 was consistent with the presence of a coiled alpha -helix in this region (Fig. 5A). Although linker-scanning mutations near the C-terminal end of the putative coiled-coil show periodicity in reducing invasiveness, they do not eliminate IpaC activity completely. In contrast, when NheI linkers (encoding Ala-Ser) were introduced into the same region, substitution for the Leu335-Ile336 pair did completely eliminate IpaC invasion function, as did substitution for Leu339-Leu340 (Fig. 5B). This difference in the effect of amino acid substitutions at this location could be explained by the fact that the Leu-Glu led to the replacement of a nonpolar pair of amino acids by a nonpolar/polar pair. On the other hand, NheI scanning results in the replacement of nonpolar residues by a polar pair. In total, these data are consistent with the presence of an alpha -helix within this portion of IpaC.


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Fig. 5.   Linker-scanning mutagenesis of the putative coiled-coil region of IpaC. In A, Leu-Glu amino acid pairs, encoded by xhoI restriction sites, were used to replace existing amino acids. In each case, the number given is that of the first amino acid being replaced. In B, the same experiment was carried out using nheI restriction sites, which encode Ala-Ser pairs. AS313 and AS321 were not generated because the nheI site would have replaced codons already specific for Ala-Ser pairs. Invasion is shown relative to that directed by native IpaC using a standard gentamycin protection assay. The data shown are the average of triplicates ± S.E.

Because a single amino acid change at Ile336 and Leu340 in the putative IpaC coiled region only partially reduced the ability of IpaC to restore invasiveness, other single amino acid changes were introduced, using Pro as the substituted amino acid because of its incompatibility with alpha -helix formation. When Pro was used to replace Ser314 at the N terminus of the putative IpaC coil, invasion function was not affected. Replacement of Lys326 reduced IpaC invasion function to less than half that of native IpaC (Table II). When Ile336 was replaced with Pro, however, IpaC invasion function was reduced more than 80% (Table II). During linker-scanning analysis, the equivalent of a single amino acid change at this position (Ile336 right-arrow Glu336) resulted in only a 48% reduction. Replacement of Leu340 with Pro completely eliminated IpaC invasion function, whereas replacement with Glu only reduced invasion function 64% (Table II). The large negative effect of Pro replacement of amino acids near the C terminus of the putative IpaC coiled region, when compared with Glu substitution, is consistent with this region existing as a functionally important alpha -helix.

                              
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Table II
The effect of site-specific proline residues within the predicted coiled-coil of IpaC on invasion function

IpaC Nucleates Actin in Vitro-- It has been reported that the IpaC homologue from S. typhimurium (SipC) nucleates actin in vitro (24). We find that IpaC also nucleates actin in vitro with an efficiency that is at least equal to that of SipC (Fig. 6). Deletion of the IpaC N terminus does not affect this activity, whereas deletion of the C terminus (data not shown) or hydrophobic region does eliminate the ability of IpaC to nucleate actin (Fig. 6). Furthermore, the C-terminal addition of a 15-residue tag that eliminates IpaC effector function in vivo also eliminates the ability of IpaC to direct actin nucleation (data not shown), indicating that the C terminus of IpaC is required for actin nucleation.


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Fig. 6.   Actin nucleation was determined by incubating pyrene-actin with protein for 15 min followed by adding actin polymerization buffer. Actin polymerization is monitored as an increase in pyrene fluorescence as a function of time, and this rate is greatly accelerated by actin-nucleating proteins such as SipC or IpaC relative to proteins that do not nucleate actin such as IpaC I' or in the absence of added protein. Deletion of the IpaC C terminus (amino acids 171-363) also eliminates its actin nucleation activity (data not shown), whereas deletion of the N terminus up to amino acid 62 (IpaC Delta I) does not affect actin nucleation activity. Data shown are representative of multiple experiments. AU, arbitrary units.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

IpaC is an essential participant in the invasion process of S. flexneri (3). It is involved in actin rearrangements, pathogen entry into phagosomal vacuoles, and the subsequent lysis of those vacuoles (2, 4). Although the broad functional organization of IpaC has been described (14, 29), little is known of the structure of the protein. We find that under physiological conditions, recombinant IpaC is composed of an alpha -helix (<10%), a beta -sheet, and significant random structure (Table I). Thus, this protein may be considered a member of that recently recognized class of proteins whose native state contains a significant amount of disordered structure (30, 31).

Temperature perturbation studies show that IpaC undergoes a distinct structural transition involving both secondary and tertiary structure between 30 and 60 °C (Figs. 1 and 2). This does not involve complete unfolding since the majority of secondary structure is retained post-transition (Table I). Additionally, shifts in the derivative absorbance minima to shorter wavelengths, which would indicate exposure of buried aromatic resides to bulk solvent, were not observed. This conformational change is presumably related to temperature-induced aggregation of IpaC, as detected by turbidity measurements (Fig, 3, top). Two transitions are observed, the first between 30 and 70 °C and the second above 70 °C. This is consistent with the initial formation of soluble aggregates followed by more extensive aggregation and with previous observations that IpaC forms oligomers in solution (8). IpaC homotypic interaction involving the central hydrophobic region have also been detected using yeast two-hybrid analysis (32). The biologically relevant oligomerization state of IpaC is currently under investigation.

Examination of the N-terminal region of IpaC (IpaC I') shows reduced structural content in comparison with the wild-type protein. This is accompanied by a reduced effect of temperature on the protein. IpaC I' exhibits a small change in secondary structure above 30 °C (Fig. 1C), as well as a small tertiary structure transition between 30 and 60 °C (Fig. 2F). Differences in the environment of the aromatic residues of IpaC I', detected as shifts in derivative absorbance wavelength when compared with that of IpaC, are also observed. These shifts may also reflect differences in aromatic amino acid content. IpaC contains three Phe residues, whereas only one is present in IpaC I'. Some limited oligomerization is also observed above 50-55 °C in this form of the protein (Fig. 3).

IpaC Delta H (residues 63-170 deleted) possesses significantly less ordered structure than IpaC, verging on a completely disordered conformation as shown by the shift of the CD minima from ~204 to 200 nm (Fig. 1A). No major temperature-dependent structural changes are observed for IpaC Delta H, although slight aggregation is apparent at higher temperatures. Thus, much of the disordered structure seen in the complete protein may be reflected in the behavior of this mutant.

The C terminus region of IpaC appears to contain the coiled-coil region postulated to contribute to IpaC self-interaction and effector function. Linker-scanning analysis provides an indirect picture of this region. A periodicity in loss of invasion activity is observed with different amino acid substitutions, which is consistent with functionally significant helical structure in this region (Fig. 5). Additional substitutions of proline residues, known helix breakers, also reduce invasion activity, further supporting this hypothesis.

During IpaC-mediated Shigella invasion of epithelial cells, IpaC is inserted into the host cytoplasmic membrane and, following uptake, mediates vacuolar escape (16), possibly by disrupting the phospholipid membrane following penetration (11). Previous studies have indicated that the ability to penetrate and disrupt liposomes occurs optimally when the lipid bilayer possesses a net negative charge (11). We find, however, that although interactions are enhanced in the presence of negatively charged liposomes, IpaC also causes low level disruption of neutral liposomes. The mechanism of disruption does not appear to be purely a detergent effect since at low temperatures and in the presence of neutral liposomes, the rate and extent of fluorescein release is much less than that observed by Triton disruption of liposomes. A strong temperature dependence is observed for the IpaC-liposome interaction for both lipid compositions. With negatively charged liposomes, the extent of release increases until the temperature reaches ~30 °C, at which point IpaC is nearly as effective in dye release as Triton. In contrast, neutral liposomes exhibit a sigmoidal temperature dependence in the release process. This may reflect the structural change occurring between 30 and 60 °C in IpaC, which may produce a more "penetration-efficient" form of IpaC. Alternatively, the concurrent aggregation process occurring in this temperature range may reflect the ability of oligomerized protein to disrupt the bilayer.

Neither IpaC I' nor IpaC Delta H was able to disrupt liposomes. This is consistent with previous findings that the IpaC hydrophobic region is needed for association with Langmuir phospholipid monolayers (9). Coupled with the potential importance of the central hydrophobic region of IpaC for its overall stabilization, it is possible that this region contributes to overall tertiary structure stabilization, but when partially exposed, it directs penetration of phospholipid membranes. This is consistent with the results of ANS binding experiments in which titrations of IpaC with ANS at 40 °C demonstrate interaction of the dye with IpaC, indicating that hydrophobic regions of the protein become exposed under membrane-interactive conditions (not illustrated). As expected, little binding of ANS to the two mutants is seen over a wide temperature range.

IpaC Delta H and IpaC I' fail to nucleate actin in vitro, whereas IpaC and IpaC Delta I nucleate actin efficiently (Fig. 6). This suggests that actin nucleation requires sequences at the IpaC C terminus; however, it is possible that conformational changes induced by mutations at the C terminus are responsible for this loss of activity. The IpaC C terminus contains a sequence predicted to form a coiled-coil that may be required for effector function. From these observations and linker-scanning studies that reinforce the coiled-coil hypothesis, it seems reasonable to conclude that this helical conformation is important for some aspect of actin nucleation. This is supported by preliminary data that the purified linker-scanning mutant AS339, which cannot direct S. flexneri invasion of cultured cells, is also unable to nucleate actin in vitro (not illustrated).

An analogous ability to nucleate actin was described for SipC of S. typhimurium (24); however, SipC has not been shown to act as a "direct effector" in Salmonella invasion. It was recently reported that SspC (SipC) from S. typhimurium co-purifies with HeLa cell actin in immunoprecipitation assays, but this relationship may be mediated by interactions with keratin 8 (33). Deletions introduced at the SspC C terminus and point mutations near its C terminus (most notably a Leu to Pro mutation) eliminate its ability to restore invasiveness to a Salmonella SspC mutant (33), suggesting similar structure-function relationships for the C termini of IpaC and SspC(SipC). How such mutations affect the ability for SspC/SipC to nucleate actin are not known, but this warrants further study. In the same report, mutations at the C terminus of SspC caused the protein to no longer associate with HeLa cell membranes following incubation with S. typhimurium (33). How similar mutations influence the ability of IpaC to disrupt liposomes has yet to be determined.

As with Salmonella, the role of actin nucleation in invasion by S. flexneri is not immediately obvious. It is possible that IpaC-mediated actin nucleation: 1) contributes to the localization of actin polymerization in host cells (34, 35) or 2) permits the quick burst of actin polymerization needed for rapid entry. It is also possible that actin nucleation by IpaC has a more direct role in Shigella invasion. A recent report demonstrates that a cdc42 knockout fibroblast-like cell line is still invaded by S. flexneri, albeit only at 15% of the levels seen in wild-type cells (36). Whatever its precise role, the IpaC protein is a key element in the invasion process of S. flexneri and may provide an important therapeutic target.

In conclusion, this work presents the first structural analysis of IpaC, based on the functional organization scheme presented previously (14). IpaC appears to be partially disordered with conformational lability increasing under physiological temperature. The existence of a helical domain at the C terminus of the protein, deemed necessary for effector function in the invasion process, is probed, and the presence of such a structure is strongly supported. Additionally, the interaction of IpaC with phospholipid bilayers is further characterized, and distinct domains of the protein are identified as necessary for this interaction. Finally, in vitro actin nucleation is demonstrated for IpaC, and this activity is preliminarily localized to the C terminus.

    FOOTNOTES

* This work was supported by an NIGMS, National Institutes of Health Biotechnology Training Grant to the University of Kansas, a Bristol Myers Squibb tuition fellowship (to L. A. K.), and NIAID, National Institutes of Health funding (Grant AI34428) to (W. D. P.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§ These authors contributed equally to this work.

Present address: University of Colorado Health Sciences Center, School of Pharmacy, 4200 E. 9th Ave., Denver, CO, 80262.

** Present address: Dept. of Molecular Microbiology, University of Texas at San Antonio, Health Science Center, San Antonio, TX 78229.

Dagger Dagger To whom correspondence should be addressed. Tel.: 785-864-3299; Fax: 785-864-5294; E-mail picking@ku.edu.

Published, JBC Papers in Press, November 8, 2002, DOI 10.1074/jbc.M208383200

2 A. Harrington and W. Picking, manuscript in preparation.

3 L. A. Kueltzo and C. R. Middaugh, manuscript in preparation.

    ABBREVIATIONS

The abbreviations used are: Ipa, invasion plasmid antigens; IpaC, invasion plasmid antigen C; IpaD, invasion plasmid antigen D; ANS, 8-anilino-1-napthalene sulfonic acid; TTSS, type III secretion system; MEM, minimum Eagle's medium; SipC, Salmonella invasion protein C.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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