Abstract
Since their discovery over twenty years ago, eukaryotic-like transmembrane receptor Ser/Thr protein kinases (STPKs) have been shown to play critical roles in the virulence, growth, persistence and reactivation of many bacteria. Information regarding the signals transmitted by these proteins, however, remains scarce. To enhance understanding of the basis for STPK receptor signaling, we determined the 1.7-Å-resolution crystal structure of the extracellular sensor domain of the Mycobacterium tuberculosis receptor STPK, PknH (Rv1266c). The PknH sensor domain adopts an unanticipated fold containing two intramolecular disulfide bonds and a large hydrophobic and polar cleft. The residues lining the cleft and those surrounding the disulfide bonds are conserved. These results suggest that PknH binds a small-molecule ligand that signals by changing the location or quaternary structure of the kinase domain.
Keywords: orphan receptor, virulence, Rv1266c
Introduction
Mycobacterium tuberculosis (Mtb) is a persistent human pathogen that currently infects one-third of the world's population and causes over 1.7 million deaths per year.1 The pathogenicity of Mtb stems from its ability to alter its developmental programs and metabolism in different host niches. After phagocytosis by alveolar macrophages, Mtb slows growth and alters the composition of cell wall mycolic and fatty acids to survive the nutrient poor phagocytic environment and resist microbicides such as nitric oxide and reactive oxygen species.2 However, little is known about the developmental programs and molecular signals that trigger these adaptive responses. Candidate sensor molecules for transmitting environmental signals into adaptive responses include the 11 eukaryotic-like Ser/Thr protein kinases (STPKs) encoded in the Mtb genome, nine of which have an intracellular N-terminal kinase domain linked via a single transmembrane helix to an extracellular C-terminal sensor domain.3 Recent sequencing projects indicate eukaryotic-like STPKs exist in many prokaryotes, including a wide range of pathogenic bacteria.4 Since their discovery, STPKs have been shown to regulate diverse cellular functions, such as exit from dormancy,5,6 protein secretion,7 cell division,8 sporulation,9,10 and cell-wall biosynthesis.11
The first bacterial STPK kinase domain (KD) structures, which revealed nucleotide complexes of the Mtb PknB KD, demonstrated that bacterial and eukaryotic STPKs share close structural similarities and common modes of substrate recognition and regulation.12,13 Despite advances in understanding the kinase domains of STPKs, only two of the Mtb STPK sensor domains have been structurally characterized. The PknD sensor domain structure was found to form a rigid, six-bladed beta-propeller with a flexible linker to the transmembrane helix,14 while the PknB sensor domain was found to have four PASTA domains15 that bind peptidoglycan fragments and localize the kinase to sites of peptidoglycan turnover to regulate cell growth and division.5,16 To further understanding of STPK receptor signaling, we determined the X-ray crystal structure of the extracellular sensor domain of the Mtb STPK PknH (Rv1266c).
Protein production and structure determination
To characterize the PknH sensor, we expressed the extracellular domain (ECD; residues 435–626) beginning eight residues after the predicted transmembrane helix. This N-terminally His6-tagged protein was largely insoluble in E. coli. The presence of four conserved Cys residues suggested that the structure may be stabilized by one or two disulfide bonds. To test this idea, we isolated inclusion bodies, denatured the protein in 6 M guanidine-hydrochloride (GuHCl), and re-folded it on a Ni-NTA column by stepwise dilution of the GuHCl in the presence of a 10:1 mixture of reduced-to-oxidized glutathione. This procedure yielded soluble ECD that was sensitized to proteolysis and precipitation when reduced, suggesting the disulfides are essential for the stability of the fold. The oxidized protein crystallized after removal of the purification tag. The crystal structure was determined at 1.7-Å resolution by single-wavelength anomalous diffraction (SAD) analysis of a terbium derivative (Table 1). The entire sequence from residues 435 to 626 was ordered.
Table 1.
Data Collection | PknH ECD Tb3+ Complex |
---|---|
Wavelength (Å) | 1.12 |
Temperature (K) | 100 |
Space group | P21 |
Unit cell parameters | |
a, b, c (Å) | 47.46, 35.92, 49.31 |
β(°) | 98.36 |
Resolution (Å) a | 50.0-1.70 (1.76–1.70) |
Number of unique reflections | 34200 (3328) |
Rsym (%) | 6.1 (25.3) |
I/σI | 17.4 (4.9) |
Completeness (%) | 98.8 (98.1) |
Redundancy | 3.8 (3.8) |
SAD Solution | |
Proteins per a.u. | 1 |
Terbium Sites per a.u. | 2 |
Mean figure of merit | 0.424 |
Refinement | |
Resolution (Å) | 48.78-1.70 |
Number of reflections | 34190 |
Rwork/Rfree (%) | 16.30 / 19.74 |
Number of atoms | |
Protein | 1467 |
Solvent | 221 |
Average B factors | |
Protein (Å2) | 17 |
Solvent (Å2) | 25 |
Rmsd | |
Bond lengths (Å) | 0.013 |
Bond angles (°) | 0.96 |
Ramachandran plot | |
Favored (%) | 96 |
Allowed (%) | 4 |
PDB ID | 4ESQ |
Notes on Table 1: Data were collected at 100 K at Beamline 8.3.1 at the Lawrence Berkeley National Laboratory Advanced Light Source.39 Data were reduced and scaled with HKL2000.40 The structure was determined using PHENIX41 and the model was adjusted manually using Coot42. Phenix.autosol found two terbium sites per asymmetric unit, and phenix.autobuild produced a model with 191 residues and an Rfree of 24% after seven cycles of automatic building and refinement. Building and refinement were completed with phenix.refine and Coot and included addition of a single ordered molecule of BIS-TRIS buffer that coordinated one of the two terbium ions. The final model was validated using MolProbity.43
PknH sensor domain structure
The PknH sensor domain contains six alpha helices and seven anti-parallel beta strands with α1-α2-α3-α4-β1-β2-α5-β3-β4-β5-β6-β7-α6 topology (Fig. 1a). Two intramolecular disulfide bonds link α3 to α5 (C482–C545) and β6 to β7 (C587–C604). A 22-residue irregular loop connects α2 and α3. The most prominent feature is a large v-shaped central cleft (Fig. 1b). Five of the seven anti-parallel beta-strands (β1/β2 and β5–β7) make up one side of this cleft, while alpha helices α3 to α5 and beta strands β3 and β4 comprise the other side. The α2-α3 loop forms the rim of the cleft, and residues 486–490 in the α3-α4 loop line the cleft inner wall (Fig. 1). The cleft has a calculated17 surface area of 1134 Å2 and volume of 2,768 Å3.
A BLAST search reveals that PknH orthologs occur only in pathogenic mycobacteria. Homologous sensor domains in STPKs generally show >50 % sequence identity. In addition, the PknH sensor domain shows 27 – 40 % sequence identity to mycobacterial LppH proteins, which contain an N-terminal lipid attachment sequence, but no kinase domain. More remote sequence homologs in Mtb include LppR, Rv3705c, LpqA, LpqQ, LprH and the PknJ sensor domain. Plotting the sequence conservation in PknH orthologs on the sensor-domain structure reveals that residues surrounding the disulfide bonds and lining the bottom of the cleft have a high degree of conservation (Fig. 2). In contrast, the residues forming the edges and surface-exposed sides of the cleft are less conserved. These results point to the recent emergence of this fold in mycobacteria and suggest that the sensor-domain homologs are adapted to bind different related ligands in different species.
Structural comparisons
No structures of proteins with similar sequences have been reported, making the structure of PknH ECD the first for its Pfam18 family (PF 14032). A search for similar structures using the DALI server19 found DIP2269, a hypothetical protein from Corynebacterium diphtheriae (PDB ID: 3V7B, Z = 9.6, rmsd = 3.6 Å over 118 aligned residues), TM1622, a GTP-binding regulator from Thermotoga maritima (PDB ID: 1VR8, Z = 8.8, rmsd = 3.5 Å over 120 aligned residues) and BT1490, an uncharacterized protein from Bacteroides thetaiotaomicron (PDB ID: 3HLZ, Z = 8.8, rmsd = 3.2 Å over 119 aligned residues). Structural alignment of PknH ECD with these three proteins using POSA20 revealed a shared core of two alpha helices and six antiparallel beta-strands (β1-β2-α5-β4 extension-β5-β6-β7-α6 in PknH, Fig. 2c) that comprises 60% of the structure. The longer, unique N-terminal segment, and an extra beta-hairpin (β3-β4) between the core elements α5 and β5 in PknH provide evidence for the new fold. Nonetheless, presence of the common core also is consistent with the idea that the PknH ECD may be a distant variant of the SCOP Mog1p fold.21 In any case, the modest Z-scores, partial alignments, distinct secondary structures, high Cα rmsds and uncharacterized activities led us to conclude that direct structural comparisons between the PknH sensor domain and the DALI search results do not provide insights into the possible functions of this STPK.
Despite the lack of close structural homologs, visual comparison between the PknH sensor domain and the glycolipid-binding Mtb lipoproteins LprG (Rv1411c22,23 and LppX (Rv2945c24 shows that all three have a large central cleft bordered on one side by a beta sheet and on the other by two to three alpha helices (Fig. 3). The cleft of PknH has a surface area of 1134 Å2 and volume of 2,768 Å3 compared to the clefts for LprG (1549 Å2 and 2679 Å3) and LppX (1375 Å2 and 2835 Å3).17
LprG is a widely distributed and conserved Mtb lipoprotein with TLR2 agonist activity that has been shown to bind the cell wall precursor molecule Ac1PIM2.22 Phosphatidylmyoinositol mannosides (PIMs) are glycolipids found in the inner and outer membrane of the cell envelopes of all mycobacteria. They consist of a phosphatidylmyoinositol lipid anchor that carries one to six mannose residues with up to four acyl chains.25 In addition to being critical structural components of the cell envelope, PIMs such as Ac1PIM2 are precursors for lipomannan and lipoarabinomannan, which modulate host-pathogen interactions over the course of a tuberculosis infection.26 LppX is another conserved Mtb lipoprotein that shares 31% sequence identity with LprG and is predicted to bind to phthiocerol dimycocerosates and transport them to the outer layer of the mycobacterial cell envelope.24
PknH function
The PknH STPK sensor domain adopts a distinctive fold with two intramolecular disulfide bonds and a large v-shaped cleft. Possible functions for the PknH sensor domain can be inferred from its genomic location and reported substrates. The pknH gene (Rv1266c) is adjacent to the gene for the EmbR transcriptional regulator (Rv1267) on the Mtb chromosome. In vitro phosphorylation by PknH enhances EmbR binding to the promoter of the embCAB arabinosyltransferase genes and leads to increased transcription of these enzymes.27 EmbA and EmbB are glycosyltransferases that create the terminal hexaarabinoside motif in Mtb cell wall arabinogalactan,28 while EmbC synthesizes the arabinan portion of lipoarabinomannan.29 Deletion of PknH in Mtb results in a hypervirulent phenotype in mice and decreased transcription of embB and embC in cultures treated with sublethal concentrations of ethambutol.30 By phosphorylating EmbR, PknH may control the ratio of lipoarabinomannan to lipomannan, a critical determinant of Mtb virulence.
In addition, PknH and several other Mtb STPKs have been shown to phosphorylate KasA, KasB, and MtFabH. KasA and KasB are β-ketoacyl-ACP synthases that elongate mycolic acid precursors.31 Mycolic acids are long-chain (C60–C90) α-alkyl-β-hydroxy fatty acids that promote bacterial resistance to antibiotics and environmental stress32 and thus increase Mtb virulence33 and persistence32. Phosphorylation-induced inhibition of KasA activity presumably leads to immature mycolic acids while phosphorylation-induced stimulation of KasB activity is thought to ensure production of the full-length mycolates required for bacterial survival and virulence.34,35 MtFabH is the β-ketoacyl-ACP synthase III enzyme that catalyzes the condensation of FAS-I derived acyl-CoAs with malonyl-AcpM, thus linking the FAS-I and FAS-II systems in Mtb.36 MtFabH is phosphorylated in vitro by PknH, PknA, and PknF.37 If PknH functions as a feedback regulator, the sensor domain may be responsive to signals generated in the complex Mtb cell wall. Alternatively, PknH may regulate cell-wall production in response to environmental cues, including compounds that are unrelated to the mycobacterial cell wall.
The novel structure of the sensor domain affords few clues about the signaling ligand(s). The putative recognition cleft is narrow, deep, and conserved, as expected for small molecule binding sites in proteins.38 Visual comparison between the cleft in PknH and the glycolipid-binding clefts of the Mtb lipoproteins LprG and LppX indicates that the PknH binding site is less hydrophobic, making it unlikely that cell-wall glycolipids are the signals. The mixed hydrophobic and polar character of the PknH cleft is consistent with a more polar signal. The stabilizing disulfides impart rigidity to the fold, and the N-terminus, which connects the domain to the TM helix, extends away from the structure. These general characteristics of structural stiffness and loose tethering to the TM helix are shared by the PknD and PknB sensor domains, implying a common signaling mechanism in which ligands may modulate the localization or oligomerization of the kinase.
Coordinates
The coordinates and structure factors were deposited in the PDB under the accession number 4ESQ.
Highlights.
Structures of two bacterial Ser/Thr kinase sensor domains have been reported.
We determined the crystal structure of the sensor domain of M. tuberculosis PknH.
The structure reveals a conserved ligand-binding cleft.
PknH likely binds a molecule that regulates kinase localization or oligomerization.
Acknowledgments
We thank James Holton, George Meigs, and Jane Tanamachi at Beamline 8.3.1 at Lawrence Berkeley National Laboratory for crystallographic assistance. This work was supported by NIH grants R01 GM70962 and P01 AI095208 to T.A.
Abbreviations
- STPK
Ser/Thr protein kinase
- Mtb
Mycobacterium tuberculosis
- KD
kinase domain
- ECD
extracellular domain
- SAD
single-wavelength anomalous diffraction
- GuHCl
guanidine hydrochloride
- TEV
tobacco etch virus
- a.u.
asymmetric unit
- rmsd
root mean square deviation
- PDB
Protein Data Bank
Footnotes
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