(Received for publication, December 23, 1996, and in revised form, February 27, 1997)
From the Department of Chemistry and Biochemistry, School of Medicine and Revelle College, University of California at San Diego, La Jolla, California 92093-0601
A lysophospholipase (LysoPLA I) has been purified and characterized from the mouse macrophage-like P388D1 cell line (Zhang, Y. Y, and Dennis, E. A. (1988) J. Biol. Chem. 263, 9965-9972). This enzyme has now been sequenced, cloned, and expressed in Escherichia coli cells. The enzyme contains 230 amino acid residues with a calculated molecular mass of 24.7 kDa. It has a high helical content in its predicated secondary structure, which is also indicated in its CD spectrum. The cloned LysoPLA I was purified to homogeneity from the transformed E. coli cells by a gel filtration column and an ion exchange column. The specific activity of the purified protein is 1.47 µmol/min·mg toward 1-palmitoyl-sn-glycero-3-phosphorylcholine at pH 8.0 and 40 °C, corresponding to the reported value of 1.3-1.7 µmol/min·mg for the protein purified from the P388D1 cells. In addition, the cloned protein cross-reacted with an antibody raised against LysoPLA I also purified from the P388D1 cells. The deduced LysoPLA I sequence contains a well conserved GXSXG motif found in the active site of many serine enzymes, and the activity of the LysoPLA I was irreversibly inhibited by the classical serine protease inhibitor diisopropyl fluorophosphate. Furthermore, site-directed mutagenesis was employed to change Ser-119 in the GXSXG motif to an Ala. The resulting mutant protein lost all of its lysophospholipase activity, even though it had the same overall protein conformation as that of the wild-type LysoPLA I. Therefore, LysoPLA I has been demonstrated to be a serine enzyme with Ser-119 at the active site.
Lysophospholipases (LysoPLAs)1 are widely distributed enzymes that hydrolyze lysophospholipids, the detergent-like intermediates in phospholipid metabolism. The in vivo levels of lysophospholipids are critical for cell survival and function, since the accumulation of lysophospholipids can perturb the activities of many membrane-bound signal-transducing enzymes (1-4), distort cell membrane integrity, and even cause cell lysis (5, 6). Several enzymes are involved in regulating lysophospholipid levels. However, LysoPLAs are considered to be the major route by which lysophospholipids are removed because of their relatively high activities (7-11).
LysoPLA activities have been identified in many mammalian tissues and cells, including human brain (10), pancreas (12, 13), eosinophil (14-16), spermatozoa (17), amnionic membranes (9), and myelocytic leukemia cell line HL-60 (18) as well as rabbit heart (11, 19), rat liver (20, 21), beef pancreas and liver (22-25), pig gastric mucosa (26), mouse macrophage cell lines P388D1 and WEHI 265.1 (7, 8, 27). However, most studies on LysoPLAs have been limited to the purification and preliminary characterization of the proteins. Research on LysoPLA is further complicated by the fact that more than one isoform of LysoPLA can exist in a single cell and that the high molecular mass enzymes (>50 kDa) generally have other enzymatic activities as well as lysophospholipase activity (12, 14, 19, 28-30). The low molecular mass enzymes (<30 kDa), on the other hand, often exhibit only lysophospholipase activity. Among the small mammalian LysoPLAs, only two have been sequenced and cloned, namely, a human Charcot-Leyden crystal protein (16.5 kDa) and a rat liver (24.7 kDa) protein (15, 20). These two LysoPLAs seem to be very different from one another in terms of their primary sequence and enzymatic properties. Despite its importance, the catalytic mechanism of LysoPLA action and the relative roles these enzymes play in regulating lysophospholipid levels in cells are largely unknown.
As part of our continuing effort to study phospholipid metabolism and its regulation in the mouse macrophage-like P388D1 cells (31), we previously reported the purification and kinetic characterization of two small lysophospholipases, LysoPLA I (27 kDa) and LysoPLA II (28 kDa) (7, 8, 32). The macrophage-like P388D1 cells express at least four enzymes that have lysophospholipase activity, providing a model system for studying the relative contribution of each enzyme to lysophospholipid metabolism in intact cells. The two large enzymes (the Group IV cytosolic PLA2 and the Group VI Ca2+-independent PLA2, both of 80-85 kDa) have PLA2 and transacylase activities as well as lysophospholipase activity (30, 31, 33, 34),2 while the small LysoPLA I and LysoPLA II are specific LysoPLAs (7, 8). In the present work, we report the sequencing, cloning, and expression of the LysoPLA I. We have also carried out inhibition and mutation studies to determine the catalytic requirements of the enzyme.
Mouse macrophage-like P388D1 cells were obtained from the American Type Culture Collection and were maintained at 37 °C in a humidified atmosphere of 90% air and 10% CO2 in Iscove's modified Dulbecco's medium (BioWhittaker) supplemented with 10% fetal bovine serum (HyClone), penicillin (100 units/ml), and streptomycin sulfate (100 mg/ml). The cell cultures were started with 105 cells/ml in 150-cm2 culture flasks. After 2 days, the cultures were inoculated into 1-liter roller bottles containing 450 ml of culture medium and incubated at 0.3 rpm on a bottle roller at 37 °C without CO2. After growing for 5 days, all of the adherent cells were suspended into the medium by agitation and then harvested by centrifugation at 700 × g for 15 min at 4 °C.
LysoPLA I Purification from P388D1 Cells, Activity Assay, and Inhibition StudyLysoPLA I was purified from the mouse macrophage-like P388D1 cells using the procedure of Zhang et al. (8). LysoPLA I activity was measured at 40 °C in 0.1 M Tris buffer (pH 8.0), 125 µM 1-[14C]palmitoyl-sn-glycero-3-phosphorylcoline (1.6 µCi/µmol) (obtained from Avanti and DuPont NEN) in a total volume of 0.5 ml. The assay was initiated by adding an aliquot of enzyme solution to the substrate mixture and incubating for the desired time. The 14C-labeled palmitic acid formed was extracted by the Dole method and then quantified by scintillation counting (7). Protein concentration was quantified by the Bio-Rad protein assay using bovine serum albumin as standard. For inhibition studies, various amounts of DFP (CalBiochem) were included in the assay mixture, and the LysoPLA I activities in the presence and absence of inhibitor were measured. To examine whether the inhibition was reversible, LysoPLA I was preincubated in the presence or absence of 63.7 mM DFP for 10 min at 40 °C and then diluted 100-fold into the enzyme assay mixture equilibrated at 40 °C. At the indicated time intervals, aliquots of the reaction were removed and quenched, and the fatty acid released was measured as described above.
Protein and DNA SequencingLysoPLA I purified from the mouse macrophage-like P388D1 cells was subjected to SDS-PAGE, and then stained by Coomassie Blue. After destaining the gel, the LysoPLA I band at about 27 kDa was cut and digested by trypsin. The resulting peptide fragments were separated by HPLC (Pharmacia Biotech Inc. Smart System), and selected peptide peaks were sequenced using a Perkin-Elmer Sequencer Precise model 492 at the Scripps' Sequencing Facility. For DNA sequencing, both strands were sequenced by the dideoxy chain termination method using a DNA sequencing kit (Amersham Corp.) and/or the automated DNA sequencer (Applied Biosystems 373 from Perkin-Elmer) at the University of California at San Diego Center for AIDS Research Molecular Biology Core.
Messenger RNA Isolation and RT-PCRTotal RNA from the mouse
macrophage-like P388D1 cells was isolated using a
guanidinium thiocyanate phenol/chloroform extraction method. Then, the
mRNA was selected from the total RNA by oligo(dT) columns
(Stratagene), and the eluted mRNA was ethanol-precipitated and
washed. Finally, the mRNA was dissolved in
diethylpyrocarbonate-treated water at about 1 mg/ml and stored at
70 °C. For RT-PCR, the first-strand cDNA was synthesized at
37 °C for 1 h using Moloney murine leukemia virus reverse
transcriptase (Stratagene) and random primers (Promega). Aliquots of
the synthesized first-strand cDNA were used to amplify the LysoPLA
I gene by PCR (Microcycler, Eppendorf) using Pfu DNA polymerase (Stratagene). The sequences of the primers used in the PCR
cycles were: primer set A (internal primers),
5
-TTTGAAGGTTACATTGGCTGGATT-3
and 5
-GCCTTGATAGATCAAGAAGTGAAG-3
;
primer set B (external primers), 5
-CGCTGTCCGCCAGCCGGTGG-3
and
5
-CGTCTACTCAAGGCCTCTTAGTGACA-3
; primer set C (cloning primers),
5
-GCGCGAATTCTCAATCAATTGGAGGTAGGAAGCTTAT-3
and
5
-CCGGCATATGTGCGGCAACAACATGTC-3
. All of these primers were custom-synthesized by Life Technology, Inc., and their positions are
indicated in Fig. 1.
Cloning and Expression of LysoPLA I
To clone the cDNA
encoding the enzyme, the open reading frame of LysoPLA I was amplified
by RT-PCR using primer set C (sequences shown above), which has the
restriction sites (EcoRI and NdeI) near the
5-ends. The amplified product was purified and then digested by
EcoRI and NdeI restriction enzymes (Pharmacia).
The digested insert was purified and ligated to the pLEX vector (pL expression system from Invitrogen) linearized by the same two restriction enzymes. The ligated products were transformed into chemically competent Escherichia coli GI724 cells. To
confirm the cloning procedures, plasmids were isolated and the insert was verified by both restriction enzyme analysis and DNA sequencing. To
express the cloned enzyme, a glycerol stock of GI724 cells harboring
pLEX/LysoPLA I vector was streaked on a RMG-Amp plate (Invitrogen) and
grown overnight at 30 °C. Then, a liquid culture in RM medium
(Invitrogen) was started from a single colony on the RMG-Amp plate, and
it was grown overnight in a 30 °C shaker. The overnight liquid
culture was diluted to A550 nm of 0.1 with the
induction medium, and incubated at 30 °C until the A550 nm reached 0.5. A tryptophan stock
solution (10 mg/ml, from Sigma) was added to a final concentration of
100 µg/ml, and the cells were put into a 37 °C shaker. After
growing to the desired time intervals, the cell density was measured,
and the cells were collected by centrifugation and stored at
20 °C
until needed.
A pair of mutagenic primers with
the Ser to Ala mutation at position 119 in the protein sequence was
synthesized (primer set D: 5-ATTTTGGGAGGATTTGCTCAGGGAGGCGCC-3
and 5
-GGCGCCTCCCTGAGCAAATCCTCCCAAAAT-3
) and used to generate
the mutated LysoPLA I (S119A) by PCR, according to the method of
QuickChange site-directed mutagenesis from Stratagene. Here, the
pLEX/LysoPLA I plasmid isolated from the GI724 cells was used as the
template for the Pfu DNA polymerase (Stratagene). After PCR,
the wild-type parent plasmids remaining in the PCR product were
selectively digested by the DpnI restriction enzyme (Stratagene), and the resultant mixture was used to transform the
chemically competent E. coli GI724 cells. The Ser to Ala
mutation at position 119 was confirmed by DNA sequencing, and it was
found to be the only change introduced in the S119A mutant when the entire coding region of the mutated cDNA was sequenced.
After protein expression had been induced by
tryptophan for about 4 h, the E. coli cells (about 500 ml) were collected by centrifugation at 4 °C. The collected cells
were resuspended in cold lysis buffer (50 mM Tris (pH 7.5),
100 mM NaCl, 1 mM dithiothreitol, 1 mM phenylmethylsulfonyl fluoride, 1 mM EDTA,
and 5% glycerol). Lysozyme (10 mg/ml, Sigma) was then added to a final
concentration of 300 µg/ml, and the cells/lysozyme were incubated at
4 °C for about 2 h. The cell debris was pelleted by
centrifugation at 20,000 × g for 30 min (4 °C) and
discarded. To the cleared supernatant, 10% streptomycin sulfate (w/v,
Sigma) was added dropwise to a final concentration of 1%. After
stirring for 20 min at 0 °C, the mixture was centrifuged at
15,000 × g for 10 min (4 °C), and the pellet was
discarded. Ammonium sulfate (Fisher) was added slowly to the cleared
supernatant to 70% saturation, and the mixture was stirred for an
additional 30 min at 0 °C to precipitate proteins. The precipitated
proteins were collected by centrifugation at 15,000 × g for 15 min, resuspended in 20 ml of cold buffer A (10 mM Tris (pH 8.0), 10 mM -mercaptoethanol,
and 2 mM EDTA), and applied to a Sephadex G-75 column
(2.5 × 80 cm, Pharmacia) already equilibrated in buffer A at
4 °C. The proteins were eluted from the column with buffer A at a
flow rate about 1.4 ml/min. The LysoPLA I fractions (as judged by
SDS-PAGE and/or enzyme activity) were pooled and loaded onto a
DEAE-Sephacel column (2.5 × 34 cm, Pharmacia) equilibrated in
buffer A. After washing the column with more than 200 ml of buffer A,
the proteins were eluted with a NaCl linear gradient (0-0.24
M) at a flow rate of 1.5 ml/min, and the LysoPLA I
fractions were saved.
CD
spectra were measured using a Cary 61 spectropolarimeter that was
modified by replacing the original Pockel cell with a 50-KHz
photoelastic modulator (Hinds International FS-5/PEM-80), used in
conjunction with a lock in amplifier (EG and G Princeton Applied
Research No. 128) to detect and integrate the modulation. System
automation, multiple scan signal averaging, and base-line subtraction
were accomplished by a DEC 11/02 computer interfaced directly to both
the Cary 61 and the amplifier. The system software and custom hardware
interfaces were designed by Allen MicroComputer Services, Inc. CD
spectra were collected at 7 °C using a cylindrical quartz cuvette
with path length of 0.5 mm. The proteins used in CD measurements were
purified from the DEAE columns (in 10 mM Tris (pH 8.0), 10 mM -mercaptoethanol, 2 mM EDTA, and 0.2 M NaCl) and were concentrated to 0.26 and 0.34 mg/ml for
the wild-type and S119A mutant, respectively. For each sample and blank
solution, 10 separate spectra were collected and averaged. The final
protein spectra were obtained by subtracting the blank spectra from the sample spectra and converting the difference to mean residue
ellipticity.
Proteins were separated by 12% SDS-PAGE along with prestained protein molecular weight markers (Bio-Rad) using the method of Laemmli (35). For Western analysis, the proteins in the gel were transferred to polyvinylidene difluoride membrane (Millipore). After blocking the nonspecific binding by 5% non-fat milk, the membrane was probed first with anti-mouse LysoPLA I antibody (8) and then with the horseradish peroxidase-linked protein A (Amersham). Finally, the protein bands were detected by the ECL system (Amersham).
Since the N terminus of the LysoPLA I purified from mouse P388D1 cells was found to be blocked for direct sequencing, the protein was subjected to trypsin digestion, and the resulting peptide fragments were separated by HPLC and then sequenced. Three peptide sequences were obtained, as indicated in Fig. 1. These peptides showed very high homology to a recently sequenced rat liver lysophospholipase (20). To obtain the sequence for the mouse LysoPLA I, mRNA from P388D1 cells was isolated, and PCR primers (shown as primer set A in Fig. 1) were designed according to the mouse peptide sequences and the codon usage of the rat lysophospholipase. RT-PCR using cDNA synthesized from the mouse mRNA gave a dominant product of about 310 base pairs, a size expected if the mouse and rat proteins have similar sequences. Furthermore, RT-PCR with primer set B, which was designed according to the sequences adjacent to the coding region of the rat protein (Fig. 1), resulted in a dominant DNA band of about 700 base pairs. For genes that are highly conserved among different species, the noncoding regions are often less conserved; however, it appears that in this case, the noncoding regions of the rat and mouse sequences are sufficiently conserved to allow primer set B to hybridize to the mouse cDNA under our RT-PCR conditions. The sequence of this 700-base pair DNA band is given in Fig. 1, along with the translated protein sequence. The deduced amino acid sequence contained all three peptide sequences that had been determined for the mouse LysoPLA I. The calculated molecular mass for the 230-residue mouse protein is 24.7 kDa, with an isoelectric point of 6.1. The mouse protein seems to have many secondary structural elements such as helix and sheet (Fig. 1), as predicted by the method of Rost (36).
The mouse LysoPLA I and the rat lysophospholipase share 95.5% homology
on the DNA level, and 96.5% on the protein level, indicating that
these two proteins are of the same origin. In addition, several other
proteins with less homology were identified using the BLAST (Basic
Local Alignment Search Tool) program (Fig. 2). This
included a Pseudomonas fluorescens protein reported as
carboxylesterase (37) and two putative esterases obtained by chromosome
sequencing of Saccharomyces cerevisiae and
Caenorhabditis elegans. As shown in Fig. 2, all of these
proteins share more than 30% homology to each other, with certain
residues conserved in all five proteins. Interestingly, the most
conserved regions include the GXSXG motif found
in the active site of serine proteases, esterases, and lipases.
To clone the cDNA encoding the mouse protein, the LysoPLA I coding region with restriction sites (EcoRI and NdeI) at the ends was amplified by RT-PCR using the mouse cDNA and primer set C. The amplified product was digested by the restriction enzymes EcoRI and NdeI and then ligated to the pLEX vector linearized by the same two restriction enzymes. The resultant pLEX/LysoPLA I was used to transform chemically competent E. coli cells. The LysoPLA I gene in the pLEX/LysoPLA I vector was confirmed by both restriction enzyme analysis and DNA sequencing.
Expression and Purification of Wild-type LysoPLA ITo verify
that pLEX/LysoPLA I indeed encoded a lysophospholipase, the
lysophospholipase activities in E. coli cells transformed either with pLEX/LysoPLA I vector, or with a control vector pLEX/LacZ (encoding -galactosidase), were examined. This expression system allows the regulated expression of foreign proteins by a tryptophan induction mechanism and is under the strong PL promoter
from bacteriophage
. After protein expression was induced by
tryptophan for different times, cells were harvested and then lysed
with lysozyme. The resultant cell homogenate was subjected to both the
lysophospholipase activity assay and Western blot analysis using the
antibody raised against the LysoPLA I from the P388D1
cells. As shown in Fig. 3A, no protein band
was recognized by the LysoPLA I antibody at the beginning of tryptophan
induction, indicating that E. coli itself does not have
LysoPLA I. However, after 90 min of induction, a protein band at about
27 kDa was recognized by the LysoPLA I antibody, and this protein band
became more intense as the induction time became longer. It should be
noted that the apparent molecular mass of this induced protein band was
the same as that of LysoPLA I purified from the mouse
P388D1 cells (Fig. 3A). Furthermore, lysophospholipase activity in E. coli cells harboring the
pLEX/LysoPLA I vector also became higher as induction time went longer.
After about 4 h of induction, it reached over 20-fold higher
activity than the control, demonstrating that the induced protein is an active lysophospholipase (Fig. 3B).
To purify the cloned LysoPLA I, E. coli cells with the
pLEX/LysoPLA I vector were induced by tryptophan for 4 h and then
harvested. After cell lysis by lysozyme, the homogenate was
centrifuged, and the supernatant was subjected first to 1%
streptomycin sulfate and then to 70% ammonium sulfate precipitation.
The resultant pellet was resuspended in Buffer A (10 mM
Tris (pH 8.0), 2 mM EDTA, and 10 mM
-mercaptoethanol) and loaded onto a Sephadex G-75 column. The
LysoPLA I-containing fractions, which were determined by both the
activity assay and SDS-PAGE, were applied to a DEAE-Sephacel column.
More than half of the active fractions from the DEAE column were
essentially free of contamination and were used for CD measurements after being concentrated. The specific activity of the purified LysoPLA
I was 1.47 µmol/min·mg, agreeing well with the reported value of
1.3-1.7 µmol/min·mg for LysoPLA I purified from mouse P388D1 cells (8).
As the mouse LysoPLA I
contains the conserved GXSXG motif (Fig. 2)
characteristic of serine proteases, esterases, and lipases, we examined
whether the classical serine protease inhibitor DFP would inhibit the
LysoPLA I activity. It was found that DFP inhibited LysoPLA I activity
with an IC50 of 5 mM under the experimental conditions employed (Fig. 4A). Furthermore,
the inhibition was found to be irreversible (Fig. 4B). As
DFP is known to inactivate serine proteins by covalent attachment to
the serine residue in the active site, the irreversible inhibition of
LysoPLA I by DFP suggested that LysoPLA I has an essential serine
residue for its function.
Site-directed Mutagenesis
To identify the serine residue that
is essential for LysoPLA I function, the Ser-119 residue in the
conserved GXSXG motif was changed to Ala by
site-directed mutagenesis. E. coli cells transformed with
the pLEX/S119A vector expressed the S119A mutant protein at about the
same efficiency as that of the wild-type protein. However, the
lysophospholipase activity in the E. coli homogenate
expressing the mutant protein was more than 10-fold lower than that of
the wild-type, just a little above the control level (Fig.
3B). When the S119A mutant protein was purified by the
procedures developed for the wild-type protein (where the mutant
protein fractions were followed by SDS-PAGE), it was found that the
activity of the purified mutant was reduced to 0.5 nmol/min·mg, significantly less than the 1470 nmol/min·mg of the wild-type enzyme
(Fig. 5).
CD Spectra of Wild-type LysoPLA I and S119A Mutant
To examine
whether the loss of the enzyme activity in the S119A mutant was due to
a conformational change in the mutant, CD spectra were measured for
both the purified wild-type protein and the S119A mutant. As shown in
Fig. 6, the CD spectra of the two proteins were
essentially identical, demonstrating that the significant loss of
enzyme activity in the S119A mutant is not the result of misfolding or
a conformational change of the S119A. In addition, the CD spectra
indicate that LysoPLA I has a high helical content, agreeing well with
its secondary structure predication (Fig. 1).
Lysophospholipids are important components of cell membranes and are involved in a variety of physiological and pathological processes. To understand the roles of LysoPLAs in lysophospholipid metabolism and cell function, we have further characterized a mouse lysophospholipase previously reported as LysoPLA I (7, 8, 32). By RT-PCR, we were able to clone the cDNA encoding an active mouse lysophospholipase, which is composed of 230 amino acid residues with a calculated molecular mass of 24.7 kDa and an isoelectric point of 6.1. Because we used primers to the noncoding regions of the rat sequence that immediately proceed and follow the coding region, it is possible that the mouse cDNA contains an additional initiator codon further upstream that is not present in the rat sequence. If such a N-terminal extension does exist, it should not be very long as the recombinant enzyme appears to have the same molecular mass as that of the native enzyme purified from the P388D1 cells (Fig. 3), and it should have little significance, since the recombinant and the native enzymes have identical characteristics and specific activity. LysoPLA I appears to have a high helical content in its secondary structure, as indicated by both its CD spectrum and the theoretical structure predication of its primary sequence. The enzyme contains a conserved GXSXG motif characteristic of many serine enzymes, and the serine residue in the center of the motif has been implicated as being part of the active site of LysoPLA I by the following evidence: 1) mutation of the central serine residue in the motif abolished all of the lysophospholipase activity (Figs. 3 and 5); 2) the global conformation of the mutant was the same as that of the wild-type protein (Fig. 6). The identification of LysoPLA I as a serine enzyme was also supported by the inhibition studies with the classical serine esterase inhibitor DFP, which inactivates serine esterases by covalent attachment to the serine in the active site. It was found that DFP inhibited the LysoPLA I activity with IC50 at 5 mM. The inhibition was essentially irreversible, presumably due to covalent modification of LysoPLA I at the active site Ser119 (Fig. 4).
Many LysoPLAs have been purified from a variety of mammalian cells.
However, no systematic groupings have been made for these LysoPLAs,
apparently due to the lack of sequence information as well as the
different conditions used to characterize the enzymes. As the sequence
of the mouse LysoPLA I is now known, we have compared it with the human
eosinophil LysoPLA (Charcot-Leyden crystal protein, 16.5 kDa) (15, 16)
and concluded that the two enzymes should be grouped differently based
on the following reasons: 1) no sequence homology was found between
them; 2) the crystal structure of the eosinophil lysophospholipase
shows that it is mainly composed of sheets, whereas LysoPLA I seems
to have a high helical content; 3) the specific activity of the
eosinophil lysophospholipase is only 0.39 nmol/min·mg, significantly
lower than that of LysoPLA I (1,300-1,700 nmol/min·mg); 4) a
putative catalytic site composed of a water, a tyrosine, and a
histidine has been identified in the crystal structure of the
eosinophil lysophospholipase, whereas LysoPLA I has been demonstrated
herein to be a serine enzyme.
On the other hand, the mouse LysoPLA I should be grouped together with the rat lysophospholipase, since the two enzymes share very high sequence homology (96% match) as well as similar properties (7, 8, 20). Other LysoPLAs that may belong to this group include (i) the major 22-kDa LysoPLA from pig gastric mucosa (26); (ii) the 24-kDa LysoPLA from HL60 (18, 20, 38); (iii) the 27-kDa LysoPLA from mouse macrophage WEHI 265.1 cells (27); (iv) the 23-kDa LysoPLA from rabbit heart (11); (v) the 25-kDa LysoPLA from beef liver (24, 25). All of these LysoPLAs exist as monomers with molecular masses around 25 kDa and are most active around pH 8. Generally, these enzymes have broad substrate specificity toward lysophospholipids, but lack other activities such as phospholipase or carboxylesterase activity. Also, the activity of all these enzymes are not affected by Ca2+, Mg2+, or EDTA. In addition, the first two enzymes in the list cross-reacted with the antibody raised against the rat liver lysophospholipase (20).
Several other enzymes that shared more than 30% homology to the mouse LysoPLA I were identified in the protein data base maintained at the National Institutes of Health, namely, a P. fluorescens carboxylesterase (37) and two putative enzymes from S. cerevisiae and C. elegans (Fig. 2). Since the sequences in the GXSXG motif region are well conserved in all these proteins, it is likely that they are serine hydrolases as well. Besides the GXSXG motif, several His and Asp residues were also conserved in these proteins, suggesting that they may form the catalytic triad (Ser-His-Asp), the catalytic mechanism found in many hydrolytic enzymes. Currently, site-directed mutagenesis experiments on LysoPLA I are in progress to identify other residues that may contribute to the catalytic triad. It is interesting to note that LysoPLA I shared sequence homology to the esterases even though it has no esterase activity.
In summary, we have sequenced, cloned, and expressed a mouse LysoPLA I, and the Ser119 in the GXSXG motif was identified to be part of the active site of the enzyme. It will be of interest to identify the other residues in the catalytic triad, but it appears that the LysoPLA is a new member of the serine enzyme superfamily.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U89352[GenBank].
We thank Dr. Chuck Rock at St. Jude Children's Research Hospital for aiding us in the data base search and Dr. Murray. Goodman at University of California at San Diego for use of his CD spectrometer.