Different Roles of DosS and DosT in the Hypoxic Adaptation of Mycobacteria

ABSTRACT The DosS (DevS) and DosT histidine kinases form a two-component system together with the DosR (DevR) response regulator in Mycobacterium tuberculosis. DosS and DosT, which have high sequence similarity to each other over the length of their amino acid sequences, contain two GAF domains (GAF-A and GAF-B) in their N-terminal sensory domains. Complementation tests in conjunction with phylogenetic analysis showed that DevS of Mycobacterium smegmatis is more closely related to DosT than DosS. We also demonstrated in vivo that DosS and DosT of M. tuberculosis play a differential role in hypoxic adaptation. DosT responds to a decrease in oxygen tension more sensitively and strongly than DosS, which might be attributable to their different autooxidation rates. The different responsiveness of DosS and DosT to hypoxia is due to the difference in their GAF-A domains accommodating the hemes. Multiple alignment analysis of the GAF-A domains of mycobacterial DosS (DosT) homologs and subsequent site-directed mutagenesis revealed that just one substitution of E87, D90, H97, L118, or T169 of DosS with the corresponding residue of DosT is sufficient to convert DosS to DosT with regard to the responsiveness to changes in oxygen tension.

Oxygen sensing is important for facultative anaerobes to adapt to changes in metabolic necessities during the transition between aerobic and anaerobic conditions. Although Mycobacterium tuberculosis (MTB) is an obligate aerobe, a gradual depletion of O 2 from its culture is known to lead to a drastic change in gene expression (8,21,24,28,34,37,39). Approximately 48 genes of M. tuberculosis were reported to be induced under early hypoxic conditions, which is mediated by the DosSR (DevSR) two-component system (16,24,34). The induction of the DosR regulon is important for survival of M. tuberculosis under hypoxic conditions and for it to enter the nonreplicating dormant state (2,19). The DosSR two-component system consists of the DosS histidine kinase (HK) and its cognate DosR response regulator (RR) (24,26,29). The DosT HK, which shares high sequence similarity to DosS over the length of their primary structures, was also found to cross talk with DosR (26,30). The N-terminal domains of DosS and DosT contain two tandem GAF domains (GAF-A and GAF-B from their N termini), and the three-dimensional structure of the GAF-A and GAF-B domains was determined (5,25). A b-type heme is embedded in the GAF-A domain, composed of one five-stranded antiparallel ␤-sheet and four ␣-helices (5,14,25,32). The heme is positioned nearly perpendicular to the ␤-sheet, and H149 and H147 of the polypeptides serve as the proximal axial ligands for DosS and DosT, respectively (5,25). The ligand-binding state at the distal axial position of heme and the redox state of the heme iron modulate the autokinase activity of DosS and DosT. The O 2 -bound (oxyferrous) and ferric forms of the HKs are inactive, whereas the unliganded ferrous (deoxyferrous) form as well as NO-and CO-bound forms are active (17,36). The heme iron of DosT is stable against autooxidation of Fe 2ϩ to Fe 3ϩ in the presence of O 2 , indicating that its conversion between deoxyferrous and oxyferrous forms is the mechanism by which DosT recognizes O 2 (17). However, the autooxidation property of oxyferrous DosS remains controversial. Kumar et al. (17) and Cho et al. (5) reported that DosS undergoes autooxidation on exposure to O 2 , while other research groups demonstrated that the oxyferrous form of DosS is stable against autooxidation (13,14,36). Recently, different roles of DosS and DosT in O 2 sensing by M. tuberculosis were suggested. DosT plays a more important role in the early phase of hypoxic conditions than DosS when the growth of M. tuberculosis is transferred from aerobic to hypoxic conditions (11).
Mycobacterium smegmatis possesses a single DevS HK that phosphorylates the DevR RR (20). The DevSR two-component system is also implemented in hypoxic adaptation of this bacterium (20). Like DosT of M. tuberculosis, the autokinase activity of M. smegmatis DevS was shown to be controlled by the ligand-binding state of its heme (18). Regarding the autooxidation property, DevS of M. smegmatis was suggested to be similar to DosT rather than DosS; i.e., the heme iron in DevS is resistant to autooxidation from an oxyferrous to a ferric state in the presence of O 2 (18).
In this paper we report several lines of evidence for the functional difference between DosS and DosT in the hypoxic adaptation of mycobacteria and discuss the implications of these findings.

MATERIALS AND METHODS
Bacterial strains, plasmids, and culture conditions. The bacterial strains and plasmids used in this study are listed in Table 1. M. smegmatis strains were grown in Middlebrook 7H9 medium (Difco, Sparks, MD) supplemented with 0.2% (wt/vol) glucose as a carbon source and 0.02% (vol/vol) Tween 80 as an anticlumping agent at 37°C. M. smegmatis strains were grown either aerobically in a 250-ml Erlenmeyer flask filled with 100 ml of 7H9-glucose medium on a gyratory shaker (200 rpm) to an optical density at 600 nm (OD 600 ) of 0.5 or under hypoxic conditions in a 250-ml flask filled with 150 ml of 7H9-glucose medium (the ratio of headspace volume to culture volume was 0.87) and tightly sealed with a rubber stopper on a gyratory shaker (200 rpm) for 20 or 50 h following inoculation of the medium with aerobically grown preculture to an OD 600 of 0.05, which allowed a gradual depletion of O 2 from the growth medium. When methylene blue (1.5 g/ml) was added to the hypoxic culture medium as an oxygen indicator, the complete decolorization of methylene blue was observed to occur at between 33 and 34 h after the cultivation was initiated. When required, hygromycin (50 g/ml) was added to the growth medium. Escherichia coli strains were grown in Luria-Bertani (LB) medium at 37 or 30°C. When required, hygromycin (200 g/ml) or ampicillin (100 g/ml) was added to the growth medium for E. coli.
DNA manipulation and electroporation. Standard protocols or manufacturer's instructions were followed for recombinant DNA manipulations (31). The introduction of plasmids into M. smegmatis strains was carried out by electroporation as described elsewhere (35).
Construction of a devS mutant. To construct a devS mutant, a 1,847-bp fragment containing the devS gene was amplified from chromosomal DNA of M. smegmatis by PCR using Pfu DNA polymerase and the primer pair SF-BamHI (5Ј-GCCGGGATCCGACGAAAGTG-3Ј) and DevS-M-XhoI (5Ј-AAGCCTCG AGGAACTCGACCG-3Ј). The PCR product was restricted with BamHI and XhoI and cloned into pBluescript II KSϩ to give the plasmid pBSDevS. A 69-bp PstI fragment was deleted by restriction of pBSDevS with PstI and self-ligation of the vector part, resulting in the plasmid pBSDevS2. Finally, a 1,778-bp BamHI-XhoI fragment from pBSDevS2 was cloned into the suicide vector pKO, yielding the plasmid pKO⌬devS. The resulting plasmid, pKO⌬devS, was introduced into M. smegmatis mc 2 155 by electroporation to generate a ⌬devS mutant. Heterogenotes of M. smegmatis, generated by a single recombination event, were selected for their hygromycin resistance on 7H9-glucose agar plates. Isogenic homogenotes were obtained from the heterogenotes after a second recombination by selecting for sucrose resistance on 7H9-glucose agar plates containing 10% (wt/vol) sucrose. The allelic exchange was verified by PCR.
Construction of plasmids used for complementation. A 1,864-bp HindIII-XbaI fragment containing dosS of M. tuberculosis was obtained by restriction of pHis-DosS with HindIII and XbaI and cloned into pBluescript II KSϩ restricted with the same enzymes, giving the plasmid pBSDosS. The HindIII-XbaI fragment from pBSDosS was cloned into the shuttle vector pNBV1 to yield pNBV1DosS.
A 1,800-bp HindIII-XbaI fragment containing dosT of M. tuberculosis from pHis-DosT was digested with HindIII and XbaI and cloned into pBluescript II KSϩ, yielding the plasmid pBSDosT. The plasmid pNBV1DosT was constructed from pBSDosT in the same way as pNBV1DosS.
To construct pNBV1SHis, a 1,715-bp fragment containing the devS gene with a tail of six histidine codons before its stop codon was amplified from pBSDevS by PCR using forward primer SF-BamHI (5Ј-GCCGGGATCCGACGAAAGT G-3Ј) and reverse primer SHis (5Ј-ATGCGGATCCTCAGTGGTGGTGATGG TGGTGGTCGGGGAGCGGCGCGGT-3Ј). The PCR product was restricted with BamHI and cloned into pUC19 to give the plasmid pUCSHis. Finally, a 1,715-bp BamHI fragment was cloned into pNBV1 restricted with BamHI, resulting in the plasmid pNBV1SHis. Construction of chimeric histidine kinases. The chimeric DosST histidine kinase consists of the GAF-A domain of DosS (M1 to A218) and the GAF-B and kinase domains of DosT (T217 to R573). The chimeric DosTS consists of the GAF-A domain of DosT (M1 to A216) and the GAF-B and kinase domains of DosS (T219 to Q578). To construct the chimeric gene for DosST, an 840-bp DNA fragment encoding the GAF-A domain of DosS was generated by PCR using pBSDosS as the template and the primer pair T7 (5Ј-CGACTCACTATA GGGCG-3Ј) and GafAS-R (5Ј-GTTCCGATGTCGCGGGTGGCCTCGATCC ACGACT-3Ј). A 1,172-bp DNA fragment encoding the GAF-B and kinase domains of DosT was obtained by PCR using pBSDosT as the template and the primers GafBT-F (5Ј-AGTCGTGGATCGAGGCCACCCGCGACATCGGAA C-3Ј) and T3 (5Ј-TAACCCTCACTAAAGGG-3Ј). In the secondary PCR, the DNA fragment encoding the chimeric DosST was then obtained by using both the primary PCR products as the templates and the T3 and T7 primers. A 2,012-bp PCR product was digested with HindIII and XbaI and ligated to pBluscript II KSϩ digested with the same restriction enzymes, yielding pBSDosST. The recombinant gene on pBSDosST was verified by DNA sequencing. The 2.0-kb HindIII-XbaI fragment from pBSDosST was cloned into the pNBV1 vector, giving the plasmid pNBV1DosST. The same strategy was used for the construction of pNBV1DosTS containing the chimeric dosTS gene. An 834-bp DNA fragment encoding the GAF-A domain of DosT was amplified by PCR using pBSDosT as the template and the primers T7 and GafAT-R (5Ј-G TGGCGATGTCACGGGTTGCCTCGATCCACGCTT-3Ј). A 1,163-bp DNA fragment encoding the GAF-B and kinase domains of DosS was generated by PCR using pBSDosS as the template and the primers GafBS-F (5Ј-AAGCGTG GATCGAGGCAACCCGTGACATCGCCAC-3Ј) and T3. The secondary PCR was performed with the primary PCR products and the T3 and T7 primers. The remaining procedure for the construction of pNBV1DosTS was the same as that described for the construction of pNBV1DosST.
Site-directed mutagenesis. To introduce point mutations E87G, H89R, D90G, H97E, V108R, V118R, and T169N into DosS, mutagenesis was carried out using the QuikChange site-directed mutagenesis procedure (Stratagene, La Jolla, CA). The plasmid pBSDosS was used as the template in PCRs using Pfu DNA polymerase. Synthetic oligonucleotides 33 to 34 bases long containing a mutated codon in the middle of their sequences were employed to mutagenize the original codons. Following the verification of mutations by DNA sequencing, 1.9-kb HindIII-XbaI fragments were cloned into pNBV1.
RT-PCR and qRT-PCR. RNA isolation from M. smegmatis strains was carried out as described elsewhere (22) after disrupting M. smegmatis cells using TRIzol (Invitrogen, Carlsbad, CA) and a Fastprep 120 beadbeater (Thermo, Milford, MA). cDNA was synthesized by RT-&GO Mastermix reverse transcriptase (MPbio, Eschwege, Germany) according to the manufacturer's instruction. Synthesis of cDNA was performed using 1 g of the isolated total RNA as the template as well as primers RT-16sr(Ϫ) (5Ј-ACAACGCTCGGACCCTAC-3Ј) and Rihsp(Ϫ) (5Ј-CGCCCGTTGGTCTCCTTCTTC-3Ј) for the 16S rRNA and hspX genes, respectively. For reverse transcription-PCR (RT-PCR), primers RT-16sr(ϩ) (5Ј-CTGGGACTGAGATACGGC-3Ј) and RT-16sr(Ϫ) for the 16S rRNA gene as well as primers Rihsp(ϩ) (5Ј-GGGTCT GCCGTCGTGGGCCTC-3Ј) and Rihsp(Ϫ) for the hspX gene were used. RT-PCR was carried out in a 20-l mixture containing 1 l of the synthesized cDNA, 15 pmol each of the primers, 0.1 mM deoxynucleoside triphosphates (dNTPs), and 0.5 unit of Taq DNA polymerase. Thermal cycling began with an initial step at 94°C for 5 min, followed by 15 cycles of 94°C for 1 min, 52°C for 30 s, and 72°C for 14 s, and ended with a step at 72°C for 5 min. For quantitative real-time PCR (qRT-PCR), the same primer sets as described for RT-PCR were employed. PCR was performed using DyNamo SYBR green qPCR kit (Bio-Rad, Hercules, CA). qRT-PCR was performed in a 20-l mixture containing 10 ng of the template cDNA, 15 pmol of each of the primers, 10 l of iQ SYBR green Supermix (Bio-Rad), and 7 l of distilled H 2 O. Thermal cycling began with and initial step at 94°C for 5 min, followed by 40 cycles of 94°C for 1 min, 52°C for 30 s, and 72°C for 14 s. qRT-PCR data were analyzed with MJ Opiconmonitor analysis software version 3.1 (Bio-Rad). smegmatis was performed. The reporter gene used in the complementation test was the hspX gene, whose expression was known to be strongly induced under hypoxic conditions by the DevSR two-component system (3,7,9,10,21,34,39,43). To examine whether the introduction of the devS, dosS, and dosT genes into the ⌬devS mutant strain of M. smegmatis led to the complementation of a devS mutant phenotype, hspX gene expression was determined by RT-PCR (Fig. 2). The ⌬devS mutant strain of M. smegmatis with the empty pNBV1 vector was used as a negative control. As expected, expression of hspX in the ⌬devS mutant strain with pNBV1 was not induced under  (11). This suggestion led us to examine the possibility that the duration of hypoxic conditions in the experiment described in Fig. 2 (20 h) might be too short to activate the kinase activity of DosS. As shown in Fig. 3, expression of hspX was not induced in the ⌬devS mutant strain with DosS which was grown under hypoxic conditions for 20 h. However, when the ⌬devS mutant with DosS was grown under hypoxic conditions for 50 h, hspX expression was slightly induced. In contrast, expression of hspX was strongly induced in the ⌬devS mutant with DosT grown under hypoxic conditions for 20 h and was significantly reduced, to the level observed in the ⌬devS mutant with DosS, when the mutant strain was grown under hypoxic conditions for 50 h. The ⌬devS mutant with DevS showed the same expression pattern of hspX as the ⌬devS mutant with DosT, which is in good agreement with the complementation results. As expected, the hspX gene was not induced in the ⌬devS mutant harboring the empty vector pNBV1 under both hypoxic conditions (20 and 50 h). These results imply the following: (i) DosT appears to respond to a decrease in oxygen tension more sensitively than DosS; (ii) the DosR regulon is induced mainly during the early phase of transition from aerobic to hypoxic conditions; and (iii) when oxygen tensions in the growth medium are gradually decreased to reach very low oxygen or anaerobic conditions, the expression of the DosR regulon is significantly reduced. This is consistent with the results of Honarker et al. (11).

The discrepancy in the complementation abilities of DosS and DosT is attributable to the difference in the primary structures of their GAF-A domains.
The results from phylogenetic analysis and complementation tests suggest that the difference between DosS and DosT regarding the complementation of the ⌬devS mutant strain of M. smegmatis might be caused by a structural difference in their GAF-A domains, which serve as the heme-binding domain. To examine this possibility, we constructed two kinds of chimeric histidine kinases, DosST and DosTS. DosST is a chimeric construct in which the GAF-A domain of DosT is replaced with that of DosS. Likewise, DosTS has the GAF-A domain of DosT instead of that of DosS (Fig. 4A). The genes encoding these constructs were As an initial attempt to identify the amino acid residues within the GAF-A domain which confer the functional difference between DosS and DosT, multiple alignment was performed on the GAF-A domains of DevS homologs belonging to the DosS and DosT subclades in the phylogenetic tree (Fig.  5). The multiple-alignment analysis of the GAF-A domains showed that seven amino acids were conserved differentially between the DosS and DosT homologs, even though the majority of the amino acids of the GAF-A domains were well conserved, implying that those amino acid residues showing specific variations between DosS and DosT might be responsible for the different functionality of DosS and DosT.
To assess the whether or not the seven differentially conserved amino acids are indeed related to the different functionality of DosS and DosT, the amino acids of DosS were replaced with those corresponding to DosT using site-directed mutagenesis. The mutated genes were cloned into pNBV1 and introduced into the ⌬devS mutant of M. smegmatis. We reasoned that the corresponding amino acid might be important quantitatively by means of qRT-PCR. As shown in Fig. 6B, the extent of hspX gene expression observed in RT-PCR correlated well with that determined by qRT-PCR assay. The levels of hspX induction in the ⌬devS mutant strains with the E87G, H97E, and L118R mutant forms of DosS were comparable to or greater than that observed for the ⌬devS mutant harboring DosT. Especially, the level of hspX expression was increased approximately 4-fold in the ⌬devS mutant with H97E DosS compared with the ⌬devS mutant with DosT. Taken together, these results indicate that just one substitution of E87, D90, H97, L118, or T169 of DosS with the corresponding residue of DosT is sufficient to convert the functionality of DosS to that of DosT.

DISCUSSION
The different roles of DosS and DosT in the hypoxic response of mycobacteria. The DosR (DevR) regulon was suggested to play a significant role in survival of mycobacteria under respiratory stress conditions such as hypoxic, NO, and CO conditions where the growth of the bacteria is halted by the inhibition of aerobic respiration (3,11,19,23,27,34,38). Several studies showed that induction of the DosR regulon occurs in the early phase of progressive hypoxia in vitro, and such an initial hypoxic response appears to prime mycobacteria for subsequent adaptation to and survival in extended and more unfavorable anaerobiosis (27,40,41). The DosR regulon is regulated by the DosR RR, whose activity is controlled by two homologous HKs, DosS and DosT. In M. tuberculosis, the dosS gene forms the same transcriptional unit with dosR and its expression is induced under hypoxic conditions, whereas the dosT gene is constitutively expressed under both aerobic and hypoxic conditions (11,30). This different expression pattern gives DosT an advantage over DosS in the initial hypoxic adaptation of M. tuberculosis during the transition from aerobic to hypoxic conditions (11).
In this study, we found by complementation tests that DosT strongly induced the expression of hspX in 20-h hypoxic culture of M. smegmatis, as was the case for DevS of M. smegmatis. In contrast, DosS did not lead to the induction of hspX in 20-h hypoxic culture of M. smegmatis. As the duration of hypoxic stress increased (50 h of hypoxic conditions), the expression of hspX by DosT was significantly reduced. Interestingly, DosS induced hspX expression at a higher level under 50 h of hypoxic conditions than under 20 h of hypoxic conditions, indicating that DosS has a lower threshold value of oxygen tension to activate the transcription of the DosR regulon than DosT and that DosT and DosS are inefficient in phosphorylation of DosR under very low oxygen or anaerobic conditions. We can rule out the possibility that the less sensitive response of DosS to hypoxia than of DosT results from the difference in their expression patterns, because dosS and dosT cloned into the expression vector have the same promoter and control regions. Our finding suggests that the presence of both DosS and DosT paralogs in M. tuberculosis is not a functional redundancy but that they play distinct roles in sensing changing oxygen tension. When M. tuberculosis is gradually transited from aerobic to anaerobic conditions, DosT appears to first respond to a decline in oxygen tension, resulting in the induction of the DosR regulon, including dosS. As the synthesis of DosS is induced and oxygen tension is further decreased, DosS plays a predominant role in the later phase of the hypoxic adaptation of M. tuberculosis. This finding is in good agreement with the results obtained by Honaker et al. (11).
Our complementation tests also showed that DosT, but not DosS, is a functional substitute for DevS of M. smegmatis. What is a property that DosT and DevS share and DosS does not have? Although it is controversial, both DevS and DosT are resistant to autooxidation of the heme iron in the presence of oxygen, whereas a deoxyferrous form of DosS is quickly autooxidized to a ferric form on exposure to oxygen (5,17,18). Since the autooxidation property of a heme is determined by the microenvironment surrounding the heme, the difference in autooxidation properties of DosS and DosT is likely attribut-   (Fig. 1). Based on our finding that E87G and L118R substitutions of DosS lead to the conversion of DosS to DosT in terms of the initial hypoxic induction of hspX (Fig. 6), the DevS homologs in the third subclade are assumed to be of the DosT type due to the presence of alanine and lysine at positions E87 and L118, respectively. It is noteworthy that the nonpathogenic mycobacteria such as M. smegmatis, M. gilvum, and M. vanbaalenii have a single DosT homolog. In contrast, most pathogenic mycobacteria contain two DevS homologs, comprising one DosS homolog and either a DosT homolog or a DevS homolog belonging to the third subclade. This finding implies that DosS homologs likely give the pathogenic mycobacteria a better chance to survive and develop pathogenicity within their hosts. In accordance with this, Converse et al. reported that the survival rate and virulence of M. tuberculosis in the mouse and guinea pig models are diminished when dosS expression is disrupted (6).
The micromilieu of the distal ligand-binding pocket might determine the different responsiveness of DosS and DosT to hypoxic conditions. The difference in the sensitivity of DosS and DosT to respond to changes in oxygen tension is likely due to the difference in their oxygen-sensing mechanism. In the case of DosT, a decrease in oxygen tension is sensed through simple changes in the ligand-binding state of the heme, i.e., from an oxyferrous to a deoxyferrous form, while DosS perceives a reduction in oxygen tension through the conversion of the redox state of its heme from a ferric to a ferrous form, which probably requires a reductase and reductant system(s) as well as sufficiently low oxygen tension (13,17). According to the model for autooxidation of myoglobin proposed by Brantley et al. (4), the binding of O 2 to the distal coordination position of the ferrous heme and the subsequent protonation of O 2 lead to spontaneous dissociation of the neutral superoxide radical with concomitant oxidation of the heme iron from Fe 2ϩ to Fe 3ϩ . A water molecule can then serve as a distal ligand of the heme in place of O 2 . Therefore, the autooxidation of the heme requires the presence of oxygen and water as well as a proton donor.
The rate of autooxidation of the heme iron is affected by the microenvironment governed by amino acid residues lining the heme-binding pocket (1,2,4). The steric hindrance to O 2 bound to the heme by the side chains of amino acid residues in the distal ligand-binding pocket promotes displacement of both O 2 and its protonated form, which results in an enhancement of the autooxidation rate (2,4). The polarity and size of the distal ligand-binding pocket are also known to influence the rate of autooxidation of the heme (1, 2, 4). Multiple-alignment analysis of the GAF-A domains of mycobacterial DosS (DosT) homologs and subsequent site-directed mutagenesis revealed that just one substitution of E87, D90, H97, L118, or T169 of DosS with the corresponding residue of DosT is enough to convert the functionality of DosS to that of DosT. Although experimental validation is required, this finding allowed us to hypothesize that a single point mutation in DosS (E87G, D90G, H97E, L118R, and T169N) leads to the inhibition of autooxidation of the heme iron of DosS. Interestingly, all the amino acid residues of DosS (E87, D90, H97, L118, and T169) identified to be responsible for functional conversion from DosS to DosT are located at the ␤1, ␤2, and ␤5 strands as well as at the ␤1-␤2 and ␣2-␣3 connecting loops that form the ligand-binding pocket on the distal side of the heme (5,25). The failure of V108R and H89R mutations in the functional conversion can be explained by the facts that V108 of DosS occurs at the ␣2 helix located on the proximal side of the heme and that H89 is conservatively substituted by arginine. This result confirms that the environment in the ligand-binding pocket on the distal side of the heme is important in determining the different functionalities of DosS and DosT. Recently, the three-dimensional structure of the DosS GAF-A domain was determined, and a hydrogen-bonding network consisting of H89, E87, and Y171 was suggested (5). The network was suggested to serve as a pathway for electron transport for the reduction of Fe 3ϩ to Fe 2ϩ (5). It is also possible that a proton is transferred via this hydrogen-bonding pathway to the O 2 molecule bound to heme to facilitate the formation of the neutral superoxide radical, which in turn leads to autooxidation of the heme iron. Since the hydrogen-bonding network is disrupted in E87G DosS, this mutant form of DosS possibly possesses a DosT-like property in terms of the autooxidation rate.
In conclusion, we demonstrated in vivo that DosS and DosT of M. tuberculosis play differential roles in hypoxic adaptation. DosT responds to a decrease in oxygen tension more sensitively and strongly than DosS, which might be attributable to their different autooxidation rates. The different responsiveness of DosS and DosT is caused by the difference in their GAF-A domains accommodating the hemes. The amino acid residues involved in the functional conversion of DosS to DosT were identified.