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J. Biol. Chem., Vol. 277, Issue 23, 20264-20269, June 7, 2002
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From the
Received for publication, November 16, 2001, and in revised form, March 27, 2002
The rice disease resistance gene,
Xa21, encodes a receptor kinase-like protein consisting of
leucine-rich repeats in the putative extracellular domain and a
serine/threonine kinase in the putative intracellular domain. The
putative XA21 kinase domain was expressed as maltose-binding and
glutathione S-transferase fusion proteins in
Escherichia coli. The fusion proteins are capable of
autophosphorylation. Phosphoamino acid analysis of the glutathione
S-transferase fusion protein indicates that only serine and
threonine residues are phosphorylated. The relative phosphorylation
rate of the XA21 kinase against increasing enzyme concentrations
follows a first-order rather than second-order kinetics, indicating an
intramolecular phosphorylation mechanism. Moreover, the active XA21
kinase cannot phosphorylate a kinase-deficient mutant of XA21 kinase.
The enzymatic activity of the XA21 kinase in a buffer containing
Mn2+ is at least 15 times higher than that with
Mg2+. The Km and
Vmax of XA21 kinase for ATP are 0.3 µM and 8.4 nmol/mg/min, respectively. Tryptic
phosphopeptide mapping reveals that multiple sites on the XA21 kinase
are phosphorylated. Finally, our data suggest that the region of XA21
kinase corresponding to the RD kinase activation domain is not
phosphorylated, revealing a distinct mode of action compared with the
tomato Pto serine/threonine kinase conferring disease resistance.
Plants are continually under attack by a variety of pathogens and
have developed a wide array of defense mechanisms to protect themselves. Genetic analyses of plant-pathogen interactions have revealed that the resistance reactions, in many cases, are controlled by two dominant loci: an avirulence (avr) gene in the pathogen and a
corresponding resistance (R) gene in the plants. Lack of either gene
results in the development of disease symptoms. These genetic
interactions are defined by the gene-for-gene theory (1).
A number of plant R genes, which confer gene-for-gene type resistance,
have been cloned and characterized from diverse plants. The encoded
proteins can be grouped into six classes based on structure: a
serine/threonine kinase, proteins with a nucleotide-binding site and
leucine-rich repeats (LRR),1
presumed extracellular LRR-containing proteins with or without a
transmembrane domain, a serine/threonine receptor-like kinase (RLK),
and a protein without significant homology to known proteins (2-5).
Among all of the cloned resistance genes, only two encode protein
kinases. The tomato Pto gene conferring resistance to
Pseudomonas syringae pv. tomato containing the
avr gene avrPto, encodes a serine/threonine
kinase (Pto) that interacts with avrPto and several other proteins
known as Ptis (6-10). The Pto kinase can autophosphorylate eight
serine and threonine residues and the autophosphorylation proceeds via
an intramolecular mechanism (11, 12). The predicted amino acid sequence
of Pto indicates that it belongs to a large subfamily of protein
kinases known as RD kinases, which have an arginine immediately
preceding the conserved catalytic aspartate (13). Consistent with other
RD kinases whose activation requires phosphorylation of the activation
domain, a region spanning the conserved sequences DFG and PE (13), Pto
autophosphorylates its activation domain in vitro (12).
Moreover, specific amino acid substitutions in this region result in
constitutive induction of the hypersensitive response in the
absence of avrPto (14).
The rice bacterial blight disease resistance gene, Xa21,
encodes a RLK protein (15). The putative extracellular domain is composed of 23 LRRs, whereas the putative intracellular domain (XA21K)
contains all the invariant amino acid residues characteristic of
serine/threonine protein kinases. Based on the mode of action of animal
receptor-tyrosine kinases (RTKs), we have hypothesized that the XA21
LRR domain acts as receptor for a plant or pathogen-produced ligand and
that upon ligand binding, XA21K undergoes autophosphorylation by an
intra- or intermolecular mechanism (16). In this report, we demonstrate
that XA21K is an active serine/threonine kinase, that
autophosphorylation of multiple residues occurs exclusively via an
intramolecular mechanism, and that the XA21K region corresponding to
the RD kinase activation domain is not phosphorylated.
Construction of XA21K Expression Plasmids--
XA21K
(amino acids 677-1025) (15) was PCR-amplified with primer 1 (5'-GGATCCGCACAAGAGAACTAAAAAGGGAGC-3') and primer 2 (5'-CAGAAGTCGATCTGAAGTGTGGCA-3'), cloned, sequenced to confirm
that no PCR error was introduced, and subcloned into the pGTK vector,
which was modified from pGEX-2T (Amersham Biosciences) (17). The
resulting plasmid was designated as pGST-XA21K and used for protein expression.
A single amino acid mutation in XA21K was introduced using the
method of Deng and Nickoloff (18). Two primers (primer 3, 5'-GGACTTGGTTGAATACTCACCAG-3'; primer 4, 5'-AAGCTTTAGTACCTCCACTGCAACA-3') were designed to introduce
mutations in the vector for mutant selection and also to substitute the
lysine 736 (Lys-736) codon of XA21K. The lysine mutation creates a
single substitution of glutamic acid for Lys-736. Candidates were
confirmed by DNA sequencing and cloned into the pGTK vector. The
resulting construct, designated pGST-XA21K-K736E, was used to express
the kinase-deficient form of XA21K.
To express XA21K as a maltose-binding protein (MBP) fusion protein,
plasmids pMBP-XA21K and pMBP-XA21K-K736E were created. Primer 5 (5'-GGATCCGTCGACCACAAGAGAACTAAAAAGGGAGC-3') and primer 6 (5'-GGATCCGTCGACCCCGGGCAGAAGTCGATCTGAAGTGTGGCA-3')
were used to amplify XA21K and its kinase-deficient mutant using
pGST-XA21K and pGST-XA21K-K736E as templates. The PCR products were
cloned into the pMal-c2X expression vector (New England Biolabs,
Beverly, MA) and confirmed by sequencing.
All other XA21K mutants used in this study were created
according to the methods from Stratagene (La Jolla, CA).
pGST-XA21K was used as a template. Primer pairs S( Expression and Purification of Fusion Proteins--
pMBP-XA21K
and pMBP-XA21K-K736E were transformed into Escherichia coli
strain ER2566 (New England Biolabs). Bacterial cells were grown in 50 ml of LB supplemented with glucose (2 g/liter) and ampicillin (50 µg/ml) to A600 of 0.5-0.6. To induce
expression of the fusion proteins,
isopropyl-1-thio-
A similar protocol was used to express and purify GST-XA21K and
GST-XA21K-K736E except that a shorter time period (40 min) was used for
isopropyl-1-thio- Autophosphorylation and Dephosphorylation Assays--
The
resin-bound fusion proteins purified above were washed with kinase
buffer (50 mM HEPES (pH 7.4), 10 mM
MgCl2, 10 mM MnCl2, 1 mM dithiothreitol). Autophosphorylation experiments were
carried out in a 30-µl reaction mixture containing 20 µl of
resin-bound protein (5 µg) and 20 µCi of [
To dephosphorylate the phosphorylated fusion proteins, the
32P-labeled XA21K proteins were washed with protein
phosphatase 1 (PP1) buffer and incubated with PP1 (New England Biolabs)
according to the manufacturer's protocol. The resulting proteins were
resolved by SDS-PAGE as described above.
For the divalent cation dependence and time course assays, the
indicated amount of MBP-XA21K was mixed with 10 µCi of
[ Phosphoamino Acid Assays--
The phosphoamino acid assay was
carried out according to Horn and Walker (19). The
autophosphorylated GST-XA21K was excised from the gel and extracted
with 50 mM NH4HCO3 (pH 8.3), 0.1%
SDS, and 0.5% 2-mercaptoethanol. The recovered protein was then
precipitated with 20% (w/v) trichloroacetic acid.
The 32P-labeled fusion protein was hydrolyzed in 50 µl of
6 N HCl (Pierce) for 1 h at 110 °C. HCl was removed
by vacuum centrifugation and the pellet was dissolved in pH 1.9 buffer
(2.2% formic acid, 7.8% acetic acid, and 100 µg/ml each
phosphoamino acids standards (Ser(P), Thr(P), and Tyr(P))
(Sigma)). The sample was loaded onto a 20 × 20-cm thin-layer
cellulose (TLC) plate (C.B.S. Scientific Co., Del Mar, CA) and
subjected to electrophoresis (horizontally at pH 1.9, 1.5 kV for
30 min and vertically at pH 3.5, 1.3 kV for 25 min) using a Hunter thin
layer electrophoresis system, model number HTLE7000 (C.B.S. Scientific
Co.). After spraying with 0.25% ninhydrin in acetone to visualize the
standard phosphoamino acids, the plate was subjected to autoradiography.
Phosphopeptide Mapping--
For phosphopeptide mapping, the
recovered 32P-labeled fusion protein was oxidized in 50 µl of cold performic acid for 60 min. The performic acid was removed
with vacuum centrifugation and the pellet was resuspended in 50 µl of
50 mM NH4HCO3 (pH 8.3), and
digested overnight with L-1-tosylamido-2-phenylethyl
chloromethyl ketone-treated trypsin (Worthington) at 37 °C. After
repeated drying and resuspension in water for three times, the sample
was dissolved in pH 1.9 buffer and loaded onto a TLC plate. The tryptic phosphopeptides were resolved by electrophoresis in the first dimension
(pH 1.9, 1.5 kV, 40 min) followed by ascending chromatography about
12 h in phosphopeptide buffer (75:50:15:60,
n-butanol:pyridine:acetic acid:water). The plate was
subjected to autoradiography to visualize the phosphopeptides.
XA21K Is a Functional Kinase--
To test the hypothesis that
Xa21 encodes a protein kinase, we expressed and purified
XA21K as a MBP recombinant fusion protein and assayed for
autophosphorylation. Fig. 1 shows that
the fusion protein (MBP-XA21K) is capable of autophosphorylation.
To confirm that the phosphorylated protein was MBP-XA21K rather
than a contaminating bacterial protein, a mutated MBP-XA21K construct
was generated using the site-directed mutagenesis approach. A single
base substitution replaced Lys-736 with a glutamic acid residue.
Because Lys-736 is essential for phosphotransfer and highly conserved
in all protein kinases, the K736E mutation is expected to inactivate
XA21K. Indeed, autophosphorylation analysis of the MBP-XA21K-K736E
mutant revealed no autophosphorylation activity (Fig. 1). Similar
results were observed when XA21K was expressed as GST fusion protein
(data not shown). Because MBP and GST alone do not have any detectable
kinase activity, these results indicate that Xa21 encodes an
active kinase capable of autophosphorylation in vitro.
Characterization of XA21K--
The kinase activity of XA21K
requires the presence of divalent cations. A linear increase in the
enzymatic activity of XA21K was observed in the range of 0.1-5
mM MnCl2, followed by a plateau of the
autophosphorylation when the concentration of MnCl2 was further increased (Fig. 2A).
Magnesium chloride maintains the linear increase of the
autophosphorylation up to the highest concentration (20 mM)
used in this assay (Fig. 2B). The kinase activity of XA21K was, however, at least 15 times higher in the presence of
MnCl2 than in MgCl2 (Fig. 2C). No
detectable kinase activity was observed when CaCl2 was used
as a source of divalent cation. Time course experiments with 10 mM MnCl2 and MgCl2 indicated that
the autophosphorylation of XA21K reached a plateau after 30-40 min
(Fig. 2D).
MBP-XA21K exhibits standard Michaelis-Menten kinetics with respect to
ATP. The Km and Vmax values
for ATP, determined by a double-reciprocal plot, are 0.3 µM and 8.4 nmol/mg/min, respectively (Fig.
2E).
XA21K Is Serine/Threonine-specific--
Based on the sequence of
amino acids in kinase subdomains VI and VIII, Xa21 was
presumed to encode a serine/threonine protein kinase (15). To confirm
the serine/threonine specificity of XA21K, phosphoamino acid assays
were performed. In these assays, serine and threonine residues were
phosphorylated, whereas no detectable tyrosine residues were labeled
(Fig. 3A). Moreover, the
autophosphorylated XA21K can be dephosphorylated by the
serine/threonine phosphatase PP1 (Fig. 3B). These results
indicated that XA21K carries serine/threonine specificity.
The XA21K Autophosphorylation Occurs through an
Intramolecular Mechanism--
To test whether the autophosphorylation
of XA21K proceeds via an intramolecular (first-order with respect to
enzyme concentration) or intermolecular (second-order with respect to
enzyme concentration) mechanism, the autophosphorylation reaction was
carried out in the presence of increasing concentrations of XA21K. As
shown in Fig. 4A, the relative
phosphorylation rate increases linearly with the increasing enzyme
concentration. This result indicated that autophosphorylation of
MBP-XA21K follows first-order rather than second-order reaction
kinetics. Moreover, the phosphate incorporation per molecule of
MBP-XA21K was at the same level when the MBP-XA21K concentration in the
reaction varied from 0.7 to 44.8 µM (64 times) (Fig.
4B). The van't Hoff analysis of autophosphorylation
(logarithm of phosphorylation rate versus logarithm of
enzyme concentration) illustrated a slope of 1.03 ± 0.02 and a
correlation coefficient of 0.997 for linear regression (Fig.
4C). Our data suggested that the MBP-XA21K
autophosphorylation occurs via an intramolecular mechanism.
To confirm that intermolecular autophosphorylation does not occur, a
kinase-deficient form of XA21K (MBP-XA21K-K736E) was used as a
potential substrate for phosphorylation by GST-XA21K. Free
MBP-XA21K-K736E was incubated with free GST-XA21K. Consistent with the
results described above, GST-XA21K was unable to transphosphorylate MBP-XA21K-K736E (Fig. 4D). Similar results were obtained by
using GST-XA21K-K736E as a potential substrate for phosphorylation by MBP-XA21K (data not shown). These results, together with the
observations from the intramolecular phosphorylation assays described
above, support the notion that autophosphorylation of XA21 exclusively occurs through an intramolecular mechanism in vitro.
Multiple Serine/Threonine Residues on XA21K Are Autophosphorylated
in Vitro--
To investigate the number of autophosphorylated serine
and threonine residues, phosphopeptide mapping was carried out using both GST-XA21K and the XA21K protein without GST. XA21K was released from GST-XA21K by digestion with thrombin (Fig.
5). Because the thrombin-released XA21K
contains a 22-amino acid peptide derived from the GTK vector, we
designated the released XA21K as XA21Kt. Bands of predicted sizes of
XA21Kt and GST were observed after thrombin digestion (Fig.
5B). Autoradiography analysis showed that a protein with the
predicted size of XA21Kt was strongly phosphorylated, indicating that
this protein is XA21Kt (Fig. 5B). No radiolabeled products
at the position corresponding to GST were found. The weak bands
observed on both the Coomassie Blue-stained gel and the autoradiogram
in the GST-XA21K lanes may be the results of partial degradation of
XA21Kt.
Both GST-XA21K and XA21Kt were subjected to phosphopeptide mapping
assays to determine the phosphopeptide pattern. The
32P-labeled proteins were digested with trypsin, and the
resulting peptides were loaded onto TLC plates and resolved
horizontally by electrophoresis and vertically by ascending
chromatography. Multiple labeled spots were observed on the
autoradiograms generated from both GST-XA21K and XA21Kt (Fig.
6, A and B).
Interestingly, three spots were absent in the tryptic pattern of XA21Kt
when compared with that of GST-XA21K. Because the thrombin-released GST
is not labeled as shown in Fig. 5B, we hypothesized that the absence of three GST-XA21K-specific spots was because of the cleavage of a phosphorylated residue by thrombin. Indeed, the S(
In addition to S( The Activation Domain of XA21K Does Not Carry Any Phosphorylation
Sites--
There are seven serine and threonine residues located in
the presumed activation domain of XA21K, and all of them are included in a single tryptic peptide (Fig. 7). To
determine whether any of the residues can be autophosphorylated by
XA21K, we mutated arginine 865 (Arg-865) to histidine, which abolishes
a trypsin recognition site upstream of the seven serine and threonine
residues. Because this mutation will significantly increase the size of the tryptic peptide carrying the seven serine and threonine residues, a
shift of a labeled spot(s) on the two-dimensional autoradiogram should
be observed if the peptide contained a phosphorylated residue(s). However, tryptic mapping of the GST-XA21K-R865H mutant showed no
detectable changes on the autoradiogram when compared with that of
GST-XA21K (data not shown). To confirm this result, we further mutated
histidine 903 (His-903), downstream of the activation domain, to
arginine to create a new trypsin recognition site. Consistent with the
result from the GST-XA21K-R865H mutant, the GST-XA21K-H903R mutant
showed an identical tryptic pattern to that of the wild type GST-XA21K
(data not shown). These results suggest that the activation domain of
XA21K is not autophosphorylated in vitro.
It has long been hypothesized that protein phosphorylation plays a
key role in R gene-mediated disease resistance (20). In this paper, we
demonstrate that the presumed intracellular domain encoded by the rice
disease resistance gene Xa21 is an active serine/threonine
kinase capable of autophosphorylation. Like other protein kinases,
XA21K activity can be abolished by a single substitution of the
invariant lysine residue that is responsible for phosphotransfer. The
enzymatic properties of XA21K are also similar to those of other
characterized kinases. For instance, the MBP-XA21K
Km for ATP (0.3 µM) is comparable with
the values obtained for the epidermal growth factor receptor (0.2-3
µM), the Catharanthus roseus CrRLK1 (2-2.5
µM), and the Arabidopsis RLK5 kinases
(15.2-17.8 µM) (19, 21). Similar to CrRLK1 and the
Arabidopsis BRI1 kinases, the activity of XA21K requires
Mn2+ and Mg2+ but not Ca2+ (21,
22). These results suggest that autophosphorylation of XA21K may be an
important step in the XA21-mediated signaling.
Intermolecular autophosphorylation is particularly important for
activation of some RTKs that recognize growth factors in animal
systems. Upon ligand binding, these RTKs form homodimers triggering
intermolecular phosphorylation of regulatory residues that are
essential for activation of the kinases (23). For example, the
receptors for platelet-derived growth factor carrying intracellular tyrosine kinase domains are activated by dimerization of two receptors and subsequent intermolecular phosphorylation of the Tyr857
residue of the kinases. Here we report that autophosphorylation of
XA21K occurs through an intramolecular mechanism. Furthermore, we were
unable to detect in vitro intermolecular phosphorylation of
the XA21K-K736E mutant protein by XA21K using either resin-bound or
free fusion proteins. Similar systems were successfully used to
demonstrate that XA21K can transphosphorylate one of the XA21-binding proteins.2 Thus, our data
suggest that intermolecular autophosphorylation is not the mechanism by
which XA21K is activated. A possible mechanism for activation of the
XA21K is that a second receptor kinase forms a heterodimer with and
transphosphorylates XA21K following the infections of Xanthomonas
oryzae pv. oryzae, which in turn activates the
intramolecular autophosphorylation of XA21K.
Over the last decade, more than 20 plant disease-resistance genes have
been cloned from a variety of plant species. Only the rice
Xa21 and tomato Pto resistance genes encode
protein kinases. Although XA21K shares some common enzymatic properties
with Pto, our studies also reveal that these two kinases likely employ
distinct mechanisms for signaling. The phosphorylation status in the
activation domain of XA21K differs from that of the Pto kinase. Four of
eight identified phosphorylation sites on Pto are located on the
activation domain (12) (Fig. 7). One of them, Ser-198, is critical for avrPto-Pto-mediated elicitation of hypersensitive response. Like the
Pto kinase, there are seven serine and threonine residues in the
activation domain of XA21K (Fig. 7). Three of them are located in the
corresponding positions (including Ser-198) of the Pto phosphorylation
sites. However, our data suggest that none of these residues are
autophosphorylated, indicating that phosphorylation of the activation
domain may not be required for the XA21-mediated signaling. This is
consistent with the observations from many other non-RD kinases that
lack the conserved arginine preceding the conserved aspartate.
The RLK structure of XA21 suggests that the mode of action of this
protein may be more similar to that of RTKs rather than Pto, a
receptor-like cytoplasmic kinase (24). For instance, the extracellular
domain of RTKs is required for ligand binding. Similarly, the presumed
extracellular domain XA21 consists of LRRs that determines
race-specific recognition of the pathogen (4). Furthermore,
autophosphorylation of multiple tyrosine residues on the kinase domain
of RTKs leads to initiation of multiple responses. A classic example is
the platelet-derived growth factor receptor-mediated responses (23).
Upon platelet-derived growth factor binding to its receptor, nine
different tyrosine residues on the receptor are autophosphorylated,
resulting in the recruitment of eight distinct intracellular signaling
molecules. Because we have shown that XA21K can autophosphorylate
multiple serine and threonine residues, it is possible that XA21 can
initiate multiple defense responses by the binding of distinct
signaling proteins with specific phosphorylated residues on XA21K. In
support of this hypothesis, we have found that the active XA21K is
capable of binding to at least seven rice proteins in the yeast
two-hybrid system; however, these binding proteins showed either no or
impaired interactions with the kinase-deficient mutant
XA21K-K736E.2 Thus, we propose that one function of the
XA21K autophosphorylation is to create binding sites for recruiting
downstream signaling proteins.
We thank Dr. H. C. Kistler for allowing
use of his laboratory facility when W.-Y. S. started a new
research program; we also thank Drs. Curtis L. Hannah, John Davis, and
Pranjib K. Chakrabarty for critical reading of the manuscript.
*
This work was supported by National Science Foundation Grant
0080155 and a visiting fellowship for inter-laboratory research from
the Multi-Institutional Plant Protein Phosphorylation Group (to
W.-Y. S.) and a grant from the National Institutes of Health (to
P. C. R.). This is Florida Agricultural Experiment Station Journal Series number R-08639.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.
Published, JBC Papers in Press, April 1, 2002, DOI 10.1074/jbc.M110999200
2
L.-Y. Pi and W.-Y. Song, unpublished data.
The abbreviations used are:
LRR, leucine-rich
repeats;
GST, glutathione S-transferase;
MBP, maltose-binding protein;
RLK, receptor-like kinase;
RTK, receptor-tyrosine kinase;
XA21K, XA21 kinase;
PP1, protein phosphatase
1.
Biochemical Characterization of the Kinase Domain of the Rice
Disease Resistance Receptor-like Kinase XA21*
,,
Department of Plant Pathology, University of
Florida, Gainesville, Florida 32611, the § Division of
Biological Sciences, University of Missouri, Columbia, Missouri 65211, and the ¶ Department of Plant Pathology, University of
California, Davis, California 95616
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
8)A-For
(5'-GCAAGAAGAGCAGCTGTGGAATTCCCG-3')/S(8)A-Rev (5'-CGGGAATTCCACAGCTGCTCTTCTTGC-3'), S(21)A-For
(5'-GATCTGGTTCCGCGGGGAGCCGACTACAAAGAC-3')/S(21)A-Rev (5'-GTCTTTGTAGTCGGCTCCCCGCGGAACCAGATC-3'),
R865H-For
(5'-GATTTTGGGCTTGCACACATACTAGTTGATGGGACCTC-3')/R865H-Rev (5'-GAGGTCCCATCAACTAGTATGTGTGCAAGCCCAAAATC-3'),
and H903R-For (5'-GCTCATTGCATCAACGCGTGGAGATATTTACAGC-3')/H903R-Rev
(5'-GCTGTAAATATCTCCACGCGTTGATGCAATGAGC-3') were used to generate the S(8)A, S(21)A, R865H, and H903R
mutants, respectively.
-D-galactopyranoside was added to a
final concentration of 0.4 µM and incubated for 8 h
at room temperature. Cells were harvested by centrifugation, resuspended into column buffer (20 mM Tris-HCl (pH 7.4),
200 mM NaCl, 1 mM EDTA), supplemented with
phenylmethylsulfonyl fluoride (2 mM) and dithiothreitol (1 mM), and lysed by sonication followed by gentle agitation
at 4 °C for 10 min. The lysate was centrifuged (14,000 × g) for 10 min at 4 °C. The supernatant was mixed with 60 µl of amylose resin (New England Biolabs) followed by incubation for
1 h at 4 °C. After washing with column buffer extensively, the
fusion protein was eluted with column buffer containing 3.6 mg/ml maltose.
-D-galactopyranoside induction and that
the GST buffer (50 mM HEPES (pH 7.4), 150 mM
NaCl, 10 mM EDTA, 1 mM dithiothreitol) and
glutathione-agarose beads (Sigma) were used for purification.
-32P]ATP
(6000 Ci/mmol) (PerkinElmer Life Science, Boston, MA). The reaction was stopped after 30 min by adding 10 µl of Laemmli loading buffer (×4) and boiling for 5 min. The proteins were separated by
SDS-PAGE (7.5 or 10%). After staining with Coomassie Brilliant Blue
G-250, the gel was dried and exposed to x-ray film.
-32P]ATP in a total volume of 20 µl of kinase
buffer and divalent cation-containing buffer, respectively. For ATP
dependence assays, 2 µg of fusion protein was incubated with 0.1-50
µM cold ATP containing 3.75 µCi of
[-32P]ATP in a total volume of 30 µl of kinase
buffer and stopped at 15 min by adding 10 µl of Laemmli loading
buffer (×4). One-half of the reaction was separated by SDS-PAGE. The
Coomassie Blue-stained protein bands were recovered and then measured
using a scintillation counter. ATP incorporation was calculated based
on the radioactivity counts and the concentration of cold ATP.
Km and Vmax were estimated
according to the double-reciprocal plot and linear regression using
SigmaPlot 2000 V6 software (SPSS Inc., Chicago, IL). The intramolecular
phosphorylation assays were performed according to the method described
by Sessa et al. (11) with some modifications. Increased
amounts of fusion proteins (from 0.7 to 44.8 µM) were
used to incubate with 5 µCi of [-32P]ATP. The
reactions were stopped at 10 min by adding an equal volume of 75 mM H3PO4. One-half of the reaction
was spotted on P-81 phosphocellulose paper. The incorporated
32P was determined as described above. Van't Hoff analysis
and linear regression was carried out using SigmaPlot 2000 V6 software
(SPSS Inc.).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (21K):
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Fig. 1.
Autophosphorylation of MBP-XA21K and
MBP-XA21K-K736E. Equal amounts of affinity-purified proteins were
incubated with [ -32P]ATP in the kinase buffer
described under "Experimental Procedures" for 30 min at room
temperature. Samples were then resolved by 10% SDS-PAGE gel. Both the
Coomassie Blue-stained gel (left) and autoradiogram
(right) of the same gel are shown.
View larger version (50K):
[in a new window]
Fig. 2.
Enzymatic properties of XA21K.
Autophosphorylation of MBP-XA21K was carried out for 30 min at room
temperature in kinase buffer containing different concentrations of
MnCl2 (A), MgCl2 (B), and
10 mM of distinct divalent cations (C). Time
course experiments of MBP-XA21K were performed with 10 mM
MnCl2 and 10 mM MgCl2
(D). Samples were then resolved by 10% SDS-PAGE. Both the
Coomassie Blue-stained gel (upper) and autoradiogram
(lower) of the same gel are shown. E, the
kinetics of XA21K autophosphorylation with respect to ATP. The
double-reciprocal plot showed that the Km and
Vmax are 0.3 µM and 8.4 nmol/mg/min, respectively.
View larger version (30K):
[in a new window]
Fig. 3.
XA21K is a serine/theonine kinase.
A, phosphoamino acid assays of the autophosphorylated
GST-XA21K. The 32P-labeled GST-XA21K was hydrolyzed with
HCl and subjected to two-dimensional analysis as described under
"Experimental Procedures." The autoradiogram spots indicate the
positions of phosphorylated serine and threonine residues. Dashed
circles indicate the positions of standard phosphorylated serine,
threonine, and tyrosine. B, dephosphorylation of MBP-XA21K
by the serine/threonine phosphatase PP1. The 32P-labeled
MBP-XA21K was incubated with and without PP1 phosphatase for 30 min at
room temperature. The samples were then resolved by 10% SDS-PAGE. Both
the Coomassie Blue-stained gel (left) and autoradiogram
(right) of the same gel are shown.
View larger version (46K):
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Fig. 4.
Intramolecular phosphorylation assays of the
XA21K. Increased concentrations of MBP-XA21K (from 0.7 to 44.8 µM) were used to perform autophosphorylation as described
in the legend to Fig. 1. A, plot of phosphate incorporation
rate versus MBP-XA21K concentration. B, specific
activity of MBP-XA21K expressed as phosphate incorporation rate per
pmol of MBP-XA21K. C, van't Hoff plot of log velocity
versus the log of MBP-XA21K concentration has a slope of
1.03 ± 0.02 and a correlation coefficient of 0.997. Data in
A-C are the mean ± S.E. (n = 3).
D, GST-XA21K cannot transphosphorylate the kinase-deficient
mutant MBP-XA21K-K736E. Free GST-XA21K was incubated with free
MBP-XA21K-K736E and [ -32P]ATP in kinase buffer for 30 min at room temperature. Autophosphorylations of GST-XA21K and
MBP-XA21K-K736E were performed as controls. Samples were resolved by
7.5% SDS-PAGE. Coomassie Blue staining (left) and
autoradiogram (right) of the same gel are shown.
View larger version (31K):
[in a new window]
Fig. 5.
XA21K cannot phosphorylate the GST protein.
A, schematic diagram showing structural domains of
GST-XA21K. The 22 amino acids on XA21Kt are underlined.
S( 8) and S(21) are shown in bold and larger
size. The thrombin recognition and protein kinase A
phosphorylation sites are indicated. B, XA21Kt released by
thrombin digestion. The 32P-labeled GST-XA21K was digested
with thrombin at room temperature for 16 h. Both GST-XA21K and
thrombin were used as controls. The samples were resolved by 10%
SDS-PAGE. Coomassie Blue staining (left) and autoradiogram
(right) of the same gel are shown.
21) residue on
the 22-amino acid peptide of XA21Kt is part of the thrombin recognition
site (Fig. 5A). To test this hypothesis, we mutated S(21)
to alanine on GST-XA21K, and the mutant was subjected to phosphopeptide
mapping. As shown in Fig. 6C, the phosphopeptide pattern of
GST-XA21K-S(21)A is identical to that of XA21Kt. This result
indicates that S(21) is phosphorylated by the XA21 kinase and also
confirms that the GST portion does not contain any phosphorylation sites.
View larger version (90K):
[in a new window]
Fig. 6.
Multiple residues on XA21K are
autophosphorylated in vitro. The
32P-labeled GST-XA21K and its mutants were digested with
trypsin and subjected to two-dimensional electrophoresis and
chromatography analysis as described under "Experimental
Procedures." The autoradiogram spots are the phosphorylated peptides
generated from trypsin digestion. The origin is indicated by "+."
A, GST-XA21K; B, XA21Kt; C,
GST-XA21K-S( 21)A; D, GST-XA21K-S(8)A.
21), there is another serine residue (S(8))
located on the 22-amino acid peptide between GST and the XA21 kinase
domain (Fig. 5A). We mutated S(8) to alanine to test
whether this residue is also phosphorylated. Phosphopeptide mapping of the GST-XA21K-S(8)A showed that S(8) accounts for four phosphospots as shown in Fig. 6D. Interestingly, S(8) is located at the
protein kinase A recognition sequence. Taken together, these
results indicate that at least 20 of 27 phosphospots on the GST-XA21K
peptide map are because of autophosphorylation of XA21K, thereby
strongly suggesting that multiple residues on XA21K are autophosphorylated.
View larger version (20K):
[in a new window]
Fig. 7.
Sequence comparison of the activation domain
of XA21K and Pto. Identified phosphorylation sites on Pto (12) are
in bold. Mutated residues in the XA21K mutants (R865H and
H903R) are underlined. Arginine and lysine recognized by
trypsin on XA21K and the mutants are indicated in italic.
Tryptic peptides are boxed. X represents the
amino acids that are not shown. denotes gaps for maximal
alignment.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed: Dept. of Plant
Pathology, University of Florida, 1453 Fifield Hall, Gainesville, FL
32611-0680. Tel.: 352-392-3631 (ext. 344); Fax: 352-392-6532; E-mail:
wsong@mail.ifas.ufl.edu.
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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