Tetramers Are the Activation-competent Species of the HOCl-specific Transcription Factor HypT*

Background: The transcription factor HypT is a dynamic oligomer and is activated by methionine oxidation. Results: Dissociation of dodecamers into tetramers enhances and accelerates HypT activation by HOCl, proving tetramers to be the activation-competent species. Conclusion: HypT activity is controlled by its oligomeric state and exposure to HOCl. Significance: Regulation of a transcription factor by two levels of control enables fine-tuned activation under stress. Hypochlorous acid (HOCl) is an important component of the immune system and is produced by neutrophils to kill invading microorganisms. The transcription factor HypT is specifically activated by HOCl by methionine oxidation and protects Escherichia coli cells from the detrimental effects of HOCl. HypT forms dodecameric ring-like oligomers. Binding of HypT to DNA induces dissociation of the dodecamers into dimers and tetramers, thus forming the DNA-binding species. To dissect HypT dissociation, binding to DNA, and activation, we aimed to dissociate the dodecamers independently of DNA and to analyze HOCl-dependent activation in vitro. We found that HypT dodecamers dissociated into tetramers in the presence of l-arginine and NaCl, which was reversible upon dilution of the additive. Making use of the reversible dissociation, we generated mixed assemblies consisting of wild-type and mutant HypT subunits and determined that mutant subunits with reduced thermal stability were stabilized by wild-type HypT in the mixed assembly. HypT tetramers, as present at high NaCl concentrations, were stabilized against thermal unfolding and aggregation triggered by high HOCl concentrations. Importantly, in vitro activation by HOCl of HypT tetramers was completed within 1 min, whereas activation of dodecamers required 1 h for completion. Furthermore, activation of HypT tetramers required stoichiometric amounts of HOCl instead of an excess of HOCl, as observed for dodecamers. This supports the idea that small HypT oligomers are the activation-competent species, whereas the dodecamers are a storage form. Our study reveals the importance of the dynamic oligomeric state for HypT activation by HOCl.

Reactive oxygen species are formed as a byproduct of aerobic respiration and are further generated by the immune system and mucosal barrier epithelia to kill invading bacteria (1,2). Hypochlorous acid (HOCl) is a strongly antimicrobial reactive oxygen species with high oxidizing potential. Its bactericidal activity is due to oxidative damage to DNA, lipids, and proteins, whose accumulation leads to oxidative stress and damage to cells (3,4). HOCl damages proteins on a proteome-wide scale; methionine oxidation and oxidative unfolding and concomitant protein aggregation have been described to lead to killing of bacterial cells (5,6). Besides the damage inflicted upon proteins by HOCl, some proteins are activated by HOCl. These include the chaperone Hsp33, which in its active state prevents irreversible aggregation of proteins, and the regulators NemR, HypR, and HypT, which in turn regulate genes that support survival of the stress (6 -10). Whereas Hsp33, NemR, and HypR are activated by oxidation of cysteine thiols (7,8,11), HypT is activated by HOCl by simultaneous oxidation of three methionines (Met-123, Met-206, and Met-230) to methionine sulfoxide, thus forming the active HypT species (10). This active state can be mimicked by methionine-to-glutamine substitution, leading to the constitutively active mutant HypT M123,206,230Q (10). Both active HypT and the constitutively active mutant show strong DNA binding.
HypT is a LysR-type transcriptional regulator that specifically protects Escherichia coli cells from HOCl damage (9,12). LysR-type transcriptional regulators are ubiquitous regulators that typically form dimers and tetramers (e.g. OxyR (13), CysB (14), and NAC (15)) but can also form large oligomers such as octamers (CrgA (16)) and dodecamers (HypT (9)). The reduced HypT dodecamer is inactive. However, it dissociates into dimers and tetramers upon incubation with DNA in vitro, thus forming the DNA-binding species (9). Of note, given the reduced state of the protein, DNA binding is only weak (9,10). This DNA-induced dissociation is independent of the DNA used and occurs with nonspecific DNA and target DNA alike (9).
Changes in the oligomeric state of proteins can also be enforced by using chemical additives that are known to alter the oligomerization and increase the stability and/or solubility of proteins such as urea, L-arginine, and salt (17). Urea is used to unfold proteins for stability experiments; it denatures protein either by directly interacting with the peptide backbone and polar residues or by altering the structure and dynamics of water molecules (18). L-Arginine is widely used as an additive in refolding buffers, to increase the solubility of refolding proteins, and to stabilize proteins against aggregation (19 -22). L-Arginine suppresses intermolecular interactions between aggregation-prone polypeptides (22) and between subunits of oligomeric proteins such as ␣-crystallin, thus causing dissociation of the oligomer and simultaneously enhancing the chaperone-like activity (23). The effect of salt on protein stability and oligomerization depends largely on the kind of salt, the ionic strength, and the model substrate used (24 -28). If salt acts as a stabilizer or destabilizer is determined by the Hofmeister series. Hofmeister ions interact oppositionally with different functional groups by salting out nonpolar groups and salting in peptide groups (29,30).
In this study, we aimed to analyze the requirements for HypT activation by HOCl. Considering that the DNA-binding species, the in vivo HOCl-activated species, and the constitutively active HypT mutant are small oligomers (9, 10), we wanted to dissociate HypT dodecamers into smaller oligomers prior to activation by HOCl. Although DNA causes dissociation of HypT into smaller oligomers, the presence of DNA complicates the study of HypT activation by HOCl because DNA reacts with HOCl. Therefore, we used additives known to destabilize oligomers as a tool to dissociate the HypT dodecamer (i.e. inactive HypT) into smaller oligomers independently of DNA. We show that L-arginine and NaCl caused reversible dissociation of HypT. Reassociation did not exclusively require identical HypT species but could also be achieved using different subunits, thus allowing for generation of mixed assemblies. L-Arginine and NaCl did not cause significant conformational changes but increased the thermal stability of HypT, and NaCl also increased the stability of HypT against HOCl-induced aggregation. NaCl-induced dissociation into small oligomers strongly accelerated HypT activation by HOCl. This supports the idea that the small oligomers (i.e. the previously identified DNAbinding species (9)) are the activation-competent species and that oxidized small oligomers constitute the active species.
Analytical Ultracentrifugation-Analytical ultracentrifugation analysis was performed as described (9) using 4 -10 M protein, detecting absorbance at 280 nm. Values were corrected for buffer depending on salt and arginine concentrations. The oligomerization state was analyzed by the c(s) method provided with the SedFit software or dc/dt method analyzed with the dc/dtϩ software.
Analysis of HypT Dissociation and Reassociation-HypT (0.3-1.2 mg/ml) in storage buffer was incubated with various concentrations of L-arginine or DL-arginine (Sigma-Aldrich), NaCl, or urea (37°C, 0.5 h). These additives have been described to alter the oligomerization state of certain proteins and increase the stability and/or solubility of proteins (17). Here, these additives were used to test whether HypT dodecamers can be forced to dissociate into smaller oligomers. A 2 M L-arginine or 0.7 M DL-arginine stock solution was prepared, and the pH was adjusted to 7.5 using HCl. DL-Arginine was used for CD analysis and intrinsic fluorescence, whereas L-arginine was used for all other experiments. Reassociation after arginine or NaCl treatment was induced by diluting samples with gel filtration buffer (10 mM NaH 2 PO 4 (pH 7.5) and 0.4 M NaCl) to obtain a final concentration of 0.05 M arginine or 0.4 M NaCl (37°C, 1 h, final protein concentration of 0.03-0.1 mg/ml).
Generation of Mixed Assemblies-HypT* (without a His tag), His-tagged HypT (HypT (9)), a His-tagged mutant in which all cysteines were replaced by serine (HypT 5C3 S (12)), and the His-tagged constitutively active HypT mutant (HypT M123,206,230Q (10)) in storage buffer were incubated separately with L-arginine (L-arginine final concentration of 0.3 M, 37°C, 0.5 h). HypT* was then mixed with one of the His-tagged species. Subsequently, additives were either diluted to a final concentration of 0.05 M, removed with a PD-10 column (GE Healthcare), and protein-eluted with gel filtration buffer or removed using a Centricon 10K tube and washed with gel filtration buffer. The same effects were observed for both procedures. The final protein concentration was 0.03-0.08 mg/ml. Samples were loaded onto a HisTrap column (1-ml column volume), His-tagged assemblies were eluted with 0.5 M imidazole, and buffer was exchanged to gel filtration buffer using a NAP-5 column (GE Healthcare). Using this procedure, exclusively assemblies containing a His tag were purified.
Detection of Fluorescence (HypT*) and Western Blotting-Samples in nonreducing sample buffer were separated on a neutral pH gradient SDS gel (Serva), fluorescence was analyzed using a Typhoon scanner (9), and gels were subsequently blotted onto PVDF membrane followed by decoration with His tagspecific antibodies.
Analysis of Stability-The thermal stability of mixed assembled HypT oligomers was followed by thermal stability assays using SYPRO Orange (Invitrogen) (31). SYPRO Orange (2 l; 1:100 dilution) was added to 18 l of 1.5 M HypT (in storage buffer), and fluorescence intensity was recorded from 25 to 80°C in 55 cycles (heating rate of 1°C/min).
Analysis of HypT Solubility upon Incubation with HOCl-Dodecameric HypT (0.4 M NaCl) and tetrameric HypT (1.5 M NaCl) were incubated with various concentrations of HOCl (HOCl:HypT molar ratio of 1:1 to 200:1, 37°C, 1 h). Samples were centrifuged at 17,000 ϫ g for 20 min at 4°C, the supernatant and insoluble proteins were separated on a neutral pH gradient SDS gel, and Coomassie Blue-stained bands were quantified using the ImageJ software.

Dodecameric HypT Dissociates in the Presence of L-Arginine
and NaCl-HypT forms dodecameric ring-like structures that dissociate into dimers and tetramers upon incubation with DNA, thus forming the DNA-binding species (9). To dissect dissociation of dodecamers and binding to DNA, we aimed to dissociate HypT independently of DNA. We therefore incubated purified HypT with substances known to destabilize intermolecular interactions such as salt, urea, and L-arginine (23) and analyzed the oligomerization state by analytical ultracentrifugation. HypT sediments at 10 -11 S under standard conditions (10 mM sodium phosphate (pH 7.5) and 0.4 M NaCl (9)). The addition of urea did not significantly alter the oligomeric state of HypT, and the protein remained a large oligomer sedimenting at 10 -11 S in the presence of up to 1 M urea (Fig.  1A). In contrast, incubation of HypT with L-arginine and NaCl, respectively, resulted in gradual dissociation of dodecamers into smaller oligomers (Fig. 1, B and C). Already 0.15-0.2 M L-arginine was sufficient to generate species at 8 -9 S, likely corresponding to the hexamer (Fig. 1B). At higher concentrations of L-arginine, species sedimenting at ϳ7 S (0.25 M) and 4 S (0.3 M) were detectable, which correspond to tetramers and dimers, respectively (9). Above 0.3 M L-arginine, species sedimenting at ϳ3 S were detectable (Fig. 1B), which correspond to monomers (9). In the presence of NaCl, HypT remained a dodecamer until 0.6 M NaCl, whereas 0.8 -1.5 M NaCl generated species of ϳ6 S, corresponding to tetramers, and 2 M NaCl generated 4 S species, corresponding to dimers (Fig. 1C). Thus, we are able to dissociate the HypT dodecamer into smaller oligomers in a DNA-independent manner.
HypT Dissociation Is Reversible-Next, we hypothesized that the observed dissociation into small oligomers should be reversible upon removal of L-arginine or NaCl. Therefore, we used analytical ultracentrifugation to analyze the oligomerization state of HypT before and after dissociation and after removal of additives (Fig. 2). HypT was incubated with L-arginine (0.3 M) or NaCl (1.5 M) to induce dissociation, and samples were then diluted to yield a low final concentration of additives (0.05 M L-arginine or 0.4 M NaCl in gel filtration buffer). HypT dodecamers dissociated into 4.3 S species, corresponding to dimers (0.3 M L-arginine), and 6 S species, corresponding to tetramers (1.5 M NaCl), thus confirming the above observations. Importantly, these small oligomers reformed dodecamers that sedimented at ϳ11 S upon dilution of additives (Fig. 2). Noteworthy, dissociation and reassociation of HypT were independent of its prior concentration. Thus, we conclude that dissociation of HypT is reversible and that the different oligomeric species of HypT are in an equilibrium governed by the concentrations of L-arginine and NaCl, respectively.
HypT Forms Mixed Oligomers with HypT Mutants-Given that HypT can shift from one oligomeric state to another, we asked whether it is possible to form oligomers consisting of HypT and a HypT variant. To address this question, we tested whether mixed assemblies consisting of fluorescently labeled HypT (HypT*) and His-tagged HypT can be generated (Fig.  3A). This way, we could purify assemblies via the His tag, thus removing any homogenous HypT* assembly that did not contain a His tag. The presence of HypT* in the His-tagged assemblies can be detected via fluorescence. The simultaneous presence of fluorescence and the His tag thus indicates a mixed assembly. For a His-tagged assembly partner, we chose wildtype HypT (HypT), a HypT mutant in which all cysteines were replaced by serine (HypT 5C3 S ), and the constitutively active HypT mutant (HypT M123,206,230Q ).
We first incubated HypT* and His-tagged HypT proteins separately with 0.3 M L-arginine to dissociate them into dimers. We then mixed HypT*and one His-tagged species, each present as dimers, in various ratios and eventually diluted the samples to obtain a final concentration of 0.05 M L-arginine to induce reassociation. Thus, the smallest identical assembly was a dimer. Assemblies were purified using a HisTrap column and then used for further analysis. To test whether or not mixed assemblies were generated, samples eluted from the HisTrap column were separated by SDS-PAGE, fluorescence was then analyzed to detect HypT*, and His-tagged HypT species were additionally detected by Western blotting using antibodies specific to the His tag. When titrating HypT* to HypT 5C3 S , the fluorescence intensity increased with increasing proportions of HypT*. Simultaneously, similar amounts of HypT 5C3 S were detected in all samples, confirming that mixed assemblies were generated (Fig. 3A). Importantly, no fluorescence was detected in the sample containing only HypT 5C3 S (Fig. 3A, left lane), and the sample containing only HypT* did not bind to the His-Trap column (data not shown), demonstrating specific purification of the His-tagged protein from the HisTrap column.
As a further readout for the generation of mixed assemblies, we analyzed the thermal stability of HypT* and the individual His-tagged HypT mutants and compared it to that of the generated mixed assemblies (HypT* ϩ HypT, HypT* ϩ HypT 5C3 S , and HypT* ϩ HypT M123,206,230Q ). We used the thermal stability assay, which utilizes the fluorescent dye SYPRO Orange, which binds to exposed hydrophobic surfaces upon unfolding of proteins, thus exhibiting increased fluorescence (23). From these data, the midpoint of thermal transition (T m ) can be calculated, which represents the thermal stability of the protein. HypT and HypT* showed a similar thermal stability, with T m ϭ 55.5 Ϯ 0.8°C and 55.3 Ϯ 0.5°C, respectively (Fig.  3B). In contrast, HypT 5C3 S and HypT M123,206,230Q showed a lower thermal stability than HypT, with T m ϭ 46.7 Ϯ 0.6°C and 42.5 Ϯ 0.9°C, respectively (Fig. 3B). In contrast, the mixed assemblies demonstrated a similar thermal stability as HypT, with T m ϭ 55.8 Ϯ 0.5°C (HypT* ϩ HypT), 53.3 Ϯ 0.6°C (HypT* ϩ HypT 5C3 S ), and 53.0 Ϯ 1.0°C (HypT* ϩ HypT M123,206,230Q ) (Fig. 3B). Of note, these values are ϳ4 -5°C lower than the values observed by CD analysis (HypT, 60°C (9); HypT 5C3 S , 50.5°C (12); and HypT M123,206,230Q , 47.0°C (data not shown)), yet both methods show a striking difference in the  thermal stability of HypT and the mutants. We conclude that mixed assemblies of HypT and HypT mutants can be generated and that the HypT mutants are stabilized in a mixed assembly with HypT.
What Are the Effects of Arginine and NaCl on HypT?-To further elucidate the effect of arginine and NaCl on HypT, we analyzed the secondary structure by CD and the conformational state by intrinsic tryptophan fluorescence. Both assays were performed upon the addition of DL-arginine (0.2-0.3 M) and NaCl (0.8 -1.5 M), respectively, to induce dissociation of HypT. The secondary structure of HypT was not significantly altered either by DL-arginine (Fig. 4A, inset) or by NaCl (Fig. 4B,  inset). The intrinsic tryptophan fluorescence of HypT was only slightly altered by both additives (Fig. 4, A and B). Given that the intrinsic fluorescence intensity changed only marginally without a significant wavelength shift, this indicates that the hydrophobic environment of the fluorescent tryptophan residues did not change upon DL-arginine or NaCl addition. These results show that the overall structure (i.e. secondary and tertiary structures) of HypT does not significantly change upon dissociation of HypT into small oligomers.
Arginine and NaCl are known to stabilize proteins. Consequently, we analyzed the thermal stability of HypT in buffers containing various concentrations of additives by CD. HypT in standard buffer showed T m ϭ 59.9 Ϯ 0.7°C (compared with 55°C as determined by the thermal stability assay; see above). The addition of DL-arginine induced a small increase in thermal stability, with T m ϭ 63.7 Ϯ 0.8°C (0.3 M DL-arginine) (Fig. 4C). A more pronounced effect on the thermal stability of HypT was observed for NaCl; the T m increased to 70.1 Ϯ 0.8°C (2 M NaCl) (Fig. 4D). This shows that arginine and NaCl increase the thermal stability of HypT.
NaCl Stabilizes HypT against HOCl-induced Aggregation-Next, we tested the additive-dependent stability of HypT against HOCl-induced aggregation. HOCl is known to cause oxidative unfolding, leading to protein aggregation on a pro- teome-wide scale (6). HOCl also activates HypT in vitro and in vivo via reversible oxidation of three methionine residues to methionine sulfoxide (10). In vitro activation of HypT requires that cysteine residues are reversibly modified with glutathione before HOCl treatment, and it requires a 6:1 HOCl:HypT molar ratio. No activation is observed at lower ratios, and aggregation of HypT occurs at higher ratios (10). We hypothesized that if NaCl increases the thermal stability of HypT, it may also improve HypT stability against unfolding caused by HOCl. We used NaCl for this assay because it is chemically inert and does not react with HOCl, in contrast to arginine, whose side chain guanidinium group is a target for HOCl (32). HypT was incubated with NaCl at a final concentration of 0.4 M, at which it is present as dodecamer (standard condition), and 1.5 M, at which HypT is present as tetramer. Dodecameric HypT and tetrameric HypT were treated with different HOCl:HypT ratios (Fig.  5). Samples were centrifuged, soluble HypT was analyzed by SDS-PAGE, and band intensities were quantified. At a 12:1 HOCl:HypT molar ratio, HypT in 0.4 M NaCl aggregated significantly (Fig. 5, squares), whereas HypT in 1.5 M NaCl remained highly soluble (Fig. 5, triangles). With increasing HOCl:HypT molar ratios (up to 95:1), HypT in 0.4 M NaCl aggregated almost completely, and HypT in 1.5 M HOCl was still ϳ50% soluble (Fig. 5). Only at HOCl:HypT molar ratios above 100:1 did both proteins aggregate completely. Thus, arginine and NaCl seem to have two distinct effects on HypT: they destabilize the quaternary structure, leading to dissociation of the dodecamer, and concomitantly stabilize the small oligomers. Correlation between the Oligomeric State and HypT Activation-As mentioned above, HypT is activated in standard buffer at a 6:1 HOCl:HypT molar ratio (10). We asked whether the oligomerization state of HypT influences its activation by HOCl. To address this question, we treated S-glutathionylated HypT (HypT GSSG ) either in 0.4 M NaCl (dodecameric HypT) with a 6:1 HOCl:HypT molar ratio (10) or in 1.5 M NaCl (tetrameric HypT) with different HOCl ratios (Fig. 6). Samples were removed after different time points, and HOCl was then quenched by the addition of tris(2-carboxyethyl)phosphine, which also removed the glutathione moiety from HypT. Subsequently, samples were buffer-exchanged to standard buffer with a final concentration of 0.4 M NaCl. DNA-binding activity was analyzed by fluorescence anisotropy and compared under the different incubation conditions. We used reduced HypT (inactive, no HOCl treatment) and the constitutively active HypT M123,206,230Q mutant as controls, which showed anisotropy values of r ϭ 0.030 and r ϭ 0.070, representing low and high DNA-binding activities, respectively (10). Of note, the DNA-binding activity of HypT that was dissociated and reassociated but not treated with HOCl was higher (r ϭ 0.046) than that of reduced HypT (r ϭ 0.030). This was surprising because HypT treated as such should reform the dodecamer upon reassociation and show similar DNA binding as the original HypT. This suggests that dissociation into tetramers may cause slight changes in or close to the DNA-binding domain that are too small to be detected by CD or intrinsic tryptophan fluorescence but that are significant enough to form a more DNA bindingcompetent state.
Activation of HypT dodecamers (i.e. without prior dissociation) at a 6:1 HOCl:HypT molar ratio proceeded with a rate constant of ϳ30 min Ϫ1 . The DNA-binding activity reached its maximum after 1 h of incubation (Fig. 6, squares). Surprisingly, HypT that was dissociated into tetramers prior to the addition of HOCl was activated already at a 1:1 molar ratio to HOCl (Fig.  6, triangles). Higher HOCl ratios did not result in HypT activation, most likely because HOCl attacks other amino acids in HypT or the glutathione moiety (32), thus preventing DNA binding. Furthermore, activation of HypT tetramers at a 1:1 HOCl molar ratio was extremely fast and was complete within 1 min (Fig. 6, triangles). Given that activated HypT forms tetramers (10), such HOCl-treated tetramers, i.e. active HypT, also likely remain in this oligomerization state and are immediately  available for DNA binding. Therefore, activation at stoichiometric amounts of HOCl makes HypT a very potent HOCl sensor. We conclude that HOCl activation of HypT tetramers occurs quickly, which supports our previous results that the active form of HypT is a tetramer in vivo (9) and in vitro (10).

DISCUSSION
Arginine and NaCl are widely used as chemical additives to refold proteins and stabilize them against aggregation (17,19). Here, we used these additives as a tool to study HypT dissociation in a DNA-independent manner. Both additives were shown to dissociate the HypT dodecamer into small oligomers representing dimers and tetramers. Given that dissociation was achieved so far only in the presence of DNA (9), a DNA-independent dissociation now allows dissection of dissociation and DNA binding or activation. The observed effects of additives were nonspecific. Whereas DNA was negatively charged, arginine was positively charged. Thus, dissociation of HypT dodecamers does not depend on the charge of the component used for triggering dissociation. Furthermore, L-arginine-induced dissociation has also been described for other proteins such as ␣-crystallin, whose dissociation of the oligomer simultaneously enhances its chaperone-like activity (23). In addition, L-arginine is well known to stabilize proteins and folding intermediates and to reduce the aggregation propensity of numerous proteins (e.g. Refs. 19 and 20). Also, NaCl stabilizes proteins (e.g. Refs. 26 and 27), thus supporting the observation of increased thermal and chemical stability of HypT upon the addition of NaCl or L-arginine. However, salt ions can also promote aggregation (29) and fibrillation of proteins such as HypF, insulin, and prion proteins (28,(33)(34)(35).
The DNA-independent dissociation of HypT allowed us to analyze two effects in vitro: the activation of HypT by HOCl as well as the reassociation of different HypT species and formation of mixed assemblies of various subunits. The dissociation of HypT is reversible, therefore enabling HypT to shift from one oligomerization state to another. HypT can be present as a storage form, i.e. dodecamer, when not required in an active state (Fig. 7). If conditions change such that active HypT is required, it can form the small species from existing dodecamers, which can be activated by HOCl very quickly. Thus, HypT exists in different states: the inactive dodecamer, the DNA bindingcompetent small oligomers, the activation-competent small oligomers, and the active species, i.e. oxidized tetramers (Fig. 7). At present, it is not clear whether HOCl treatment of dodecameric HypT first triggers dissociation and then methionine oxidation or if the order is reversed (Fig. 7, middle).
When we analyzed the mixed assemblies, we observed that HypT mutants with decreased thermal stability were stabilized by the presence of wild-type HypT species in the assembly. Given that the T m values of the HypT variants are comparable when obtained by thermal stability assay after dissociation and reassociation as described in this study and CD analysis as described previously (9,12), this indicates that the dissociation and reassociation procedure itself does not influence the thermal stability of HypT and mutants. Thus, the mixed reassociation between HypT mutants and wild-type HypT leads to an increase in thermal stability, showing that the effect is derived from wild-type HypT. Considering that the smallest identical assembly is the dimer, one could assume that wild-type HypT forms more tightly packed tetramers, maybe due to more extensive stabilizing dimer-dimer contacts, which stabilize any kind of assembly containing wildtype HypT.
Changes in oligomerization as part of an activation mechanism are not unique to HypT but are described for a number of proteins, including the LysR-type transcriptional regulator CrgA (16), the bacterial DNA-binding protein Dps (36), several small heat shock proteins (see below) that function as molecular chaperones, the Bacillus subtilis AAAϩ protein ClpC (37), as well as caspases and procaspases (38). CrgA forms octameric ring-like structures that, upon binding to DNA, build a double octameric species, indicating that DNA stabilizes the larger assembly (16). Dps forms spherical dodecamers that form large biocrystals in the presence of DNA in vitro and in vivo (36). Except for small heat shock proteins, the other examples also form larger oligomers in the course of activation. In contrast, some small heat shock proteins undergo dissociation into smaller species as part of the activation mechanism. The ubiquitous small heat shock proteins form large oligomeric assemblies and protect substrate proteins from aggregation (for review, see Refs. 39 and 40). The trigger for activation may be increased temperatures and/or phosphorylation. These triggers can induce destabilization and remodeling of the large oligomer, thus causing formation of smaller oligomers with increased chaperone activity (e.g. Hsp26 (41), Hsp16.9 (42), Hsp27 (43), and ␣B-crystallin (44)). However, dissociation into smaller oligomers is not always required for efficient substrate binding, indicating that increased conformational flexibility may itself be sufficient for chaperone activity (e.g. HSP18.1 (45) and Hsp26 (46)).
At this point, it should be noted that the in vitro situation differs from the in vivo situation for HypT in wild-type E. coli cells. The salt composition and concentration in the E. coli cytosol are largely different from our in vitro buffer composition. Whereas the cytosol contains ϳ300 mM combined sodium and potassium ions (47) in addition to many other salts and macromolecules (48), our buffer contains merely 10 mM sodium phosphate and 0.4 M NaCl (plus potential additives). Previous in vitro experiments showed that the binding of RNA polymerase and lac repressor to DNA is strongly inhibited in buffers containing high salt concentrations (49,50). In contrast, such dependence was not observed in vivo at similarly high intracellular concentrations of salt (51). Richey et al. (51) suggested that not only is the salt concentration important but that also relatively larger numbers of nonspecific DNA-binding sites in in vivo compared with in vitro conditions could account for the observed difference between the in vitro and in vivo results. Likewise, the enzyme activity may be different if analyzed in a standard in vitro buffer compared with a buffer that represents the in vivo situation. van Eunen et al. (52) analyzed the kinetic parameters of glycolytic and fermentative enzymes of Saccharomyces cerevisiae in a buffer comprising the composition of the yeast cytosol. They showed that some enzymes had largely different activity in the in vivo buffer compared with the enzyme-specific optimum in vitro buffer (52). Furthermore, HypT dodecamers are the main species under strong overexpression conditions, whereas small oligomers, as typical for LysR-type transcriptional regulators, prevail in wild-type cells (9). Small oligomeric species are also increased upon HOCl stress of mildly hypT-overexpressing cells (9). HypT activation upon HOCl treatment of overproducing cells leads to maximum gene regulation within 10 min (9, 10). Taking into account that HypT activation is very quick when starting with small oligomers, this indicates that activation of HypT in wildtype cells is unequally faster. Taking further into account that  Middle, HOCl treatment of dodecamers leads to oxidation of methionine residues and concomitant dissociation of dodecamers into tetramers. This reaction proceeds fairly slowly (k ϳ 30 min Ϫ1 ) and is completed within 1 h. As a result, active HypT tetramers are formed. Right, dissociation of dodecamers into tetramers can be triggered by additives such as NaCl, thus generating activation-competent tetramers. Subsequent treatment with HOCl quickly forms active HypT (k Ͻ 1 min Ϫ1 ). Active HypT tetramers show strong DNA-binding activity.
activation requires only equimolar amounts of HOCl, this makes HypT a very sensitive HOCl probe, being perfectly equipped to immediately recognize its activating reactive oxygen species and become activated.