Abstract
Lysophosphatidic acid (LPA) is a simple bioactive phospholipid with diverse physiological actions on many cell types. LPA induces proliferative and/or morphological effects and has been proposed to be involved in biologically important processes including neurogenesis, myelination, angiogenesis, wound healing, and cancer progression. LPA acts through specific G protein-coupled, seven-transmembrane domain receptors. To date, three mammalian cognate receptor genes,lp A1/vzg-1/Edg2,lp A2/Edg4, andlp A3/Edg7, have been identified that encode high-affinity LPA receptors. Here, we review current knowledge on these LPA receptors, including their isolation, function, expression pattern, gene structure, chromosomal location, and possible physiological or pathological roles.
Lysophosphatidic acid (LPA; 1-acyl-2-sn-glycerol-3-phosphate) is a naturally occurring lysophospholipid (LP) that activates diverse cellular actions on many cell types (Fig. 1). It is also an intermediate in de novo biosynthesis of membrane phospholipids. Although all cells contain small amounts of LPA associated with membrane biosynthesis, some cellular sources can produce significant amounts of extracellular LPA such as activated platelets, which account for the LPA found in serum (Eichholtz et al., 1993). Sphingosine-1-phosphate (S1P) and sphingosylphosphorylcholine (SPC) also activate cellular responses in many cell types (Spiegel et al., 1998). LPA, S1P, and SPC each activate specific members of the G protein-coupled receptor (GPCR) superfamily.
Lysophospholipid GPCRs are encoded by the lp genes (also referred to by various orphan receptor names such asvzg/edg/mrec/gpcr26/h218/agr16/nrg-1), of which there are currently eight known members (Fig. 2). Three of these genes (lp A1–3) encode high-affinity LPA receptors (Hecht et al., 1996; An et al., 1997b,1998a; Fukushima et al., 1998; Bandoh et al., 1999; Im et al., 2000b). The other five, lp B1 throughlp B4 and lp C1, encode high-affinity S1P or SPC receptors (An et al., 1997a; Lee et al., 1998b; Zondag et al., 1998; Zhang et al., 1999; Im et al., 2000a;Van Brocklyn et al., 2000), with one study reporting that LPB1/EDG1 can also serve as a low-affinity LPA receptor (Lee et al., 1998a). In addition to the LP receptors, a dissimilar, putative LPA receptor (PSP24) has also been reported inXenopus (Guo et al., 1996), although independent confirmation of this identification has yet to emerge. This review will focus on the three confirmed mammalian LPA receptors.
Cellular Effects of LPA
The proliferative effects of LPA were first recognized in the mid-1980s (Moolenaar et al., 1986; van Corven et al., 1989). In these reports, serum-starved quiescent Rat-1 or human foreskin fibroblasts were found to respond to LPA with increased [3H]thymidine incorporation, inhibition of adenylyl cyclase (AC), increased inositol phosphates and intracellular calcium ([Ca2+]i), increased protein kinase C activity, and arachidonic acid release. The proliferation and AC responses were completely inhibited with pertussis toxin (PTX) pretreatment, which specifically inactivates Gi/o-type G proteins.
Changes in cell morphology in response to LPA were first demonstrated in the early 1990s (Dyer et al., 1992; Jalink and Moolenaar, 1992;Ridley and Hall, 1992; Tigyi and Miledi, 1992; Jalink et al., 1993). One group demonstrated that LPA induced actin cytoskeletal rearrangement of 3T3 fibroblasts, forming stress fibers through activation of the small GTPase, Rho, as demonstrated by complete inhibition of this response with Botulinum C3 toxin (Ridley and Hall, 1992). Other groups independently showed that LPA caused neurite retraction/cell rounding in cell lines of neural origin (Dyer et al., 1992; Jalink and Moolenaar, 1992; Ridley and Hall, 1992; Jalink et al., 1993).
Since these initial studies, proliferative and morphological responses to LPA have been shown in many other cell lines. Numerous other cellular and biochemical responses to LPA have also been documented (reviewed in Moolenaar et al., 1997, 1999; Chun, 1999; Chun et al., 1999). The actual mechanisms through which this detergent-like molecule acted were long uncertain, however available evidence supported the involvement of specific GPCRs (Moolenaar et al., 1997). The search for LPA receptors was hampered by a lack of specific receptor antagonists, difficulty in ligand-binding experiments, and the ubiquitous presence of LPA responsiveness in many cell types (reviewed in Chun, 1999); these factors contributed to the prolonged absence of cloned receptors for any lysophospholipid.
LPA Receptor Gene Cloning
The first LPA receptor cDNA, lp A1, was isolated using degenerate PCR from a mouse cerebral cortical neuroblast cDNA template (Hecht et al., 1996). It was named ventricular zone gene-1 (vzg-1) because of its predominant expression in the neurogenic ventricular zone of the embryonic cortex. This receptor gene encoded the first identified, high-affinity LPA receptor based on multiple criteria (Hecht et al., 1996). Several other groups also identified this gene from other species as an orphan receptor of unknown ligand specificity or function (reviewed in Chun 1999; Chun et al., 1999). Identification of this gene as encoding a LPA receptor received independent support (An et al., 1997b; Erickson et al., 1998). However, perhaps reflecting the historical difficulty in identifying a receptor, skepticism from some persisted about its identity (Allard et al., 1998; Hooks et al., 1998). Definitive studies utilizing heterologous expression in mammalian cells (Fukushima et al., 1998) or genetic deletion of lp A1 in mice (Contos et al., 2000) have eliminated such concerns. This functional information, combined with sequence and genomic structure analyses (Contos and Chun, 1998) provided a straightforward way to identify similar genes, which led to the subsequent identification of two other LPA receptors.
The second LPA receptor gene, lp A2, was identified through both an EST (expressed sequence tag) and genomic clones in the GenBank database by virtue of its substantial similarity to lp A1 (An et al., 1998a; Contos and Chun, 1998). Using homology searches, An et al. (1998a) identified two ESTs from the same cDNA clone in tumor cell libraries, and based upon functional studies, the encoded protein was determined to be another LPA receptor. The gene was called Edg4, based on its similarity with “endothelium differentiation genes(Edgs)”. At the same time, exons of the human gene were identified (Contos and Chun, 1998), and additional studies have indicated that the reported and functionally assessed Edg4receptor is actually a mutant distinct from that encoded bylp A2 (discussed further below). Nevertheless, both mutant and wild-type genes have general properties of functional LPA receptors.
The third LPA receptor gene, lp A3, was identified through degenerate PCR strategies similar to those used to isolate lp A1 (Hecht, 1996; US patent #6,057,126, filed in 1997). More recent analyses of this gene utilized cDNAs isolated by PCR from human Jurkat T cell (Bandoh et al., 1999) and human embryonic kidney 293 cell (Im et al., 2000b) cDNA to support its identification as a third LPA receptor.
Alignment of amino acid sequences for mouse and human LPA receptors is shown in Fig.3. Mouse forms of LPA1, LPA2, and LPA3 consist of 364, 348, and 354 amino acids, respectively, and molecular weight sizes estimated from the sequences are 41.2, 38.9, and 40.3 kDa, respectively. Human forms of LPA1, LPA2, and LPA3 consist of 364, 351, and 353 amino acids, respectively, and estimated molecular weights are 41.1, 39.1, and 40.1 kDa, respectively. Amino acid identities between mouse and human are 97.3% for LPA1, 90.8% for LPA2, and 90.7% for LPA3. Predicted post-translational modification sites are well conserved between species and receptor subtypes, and the modifications may account for differences between the predicted and observed molecular mass of receptor proteins. These receptors can be activated by LPA concentrations around 10 nM, depending on employed assays (Hecht et al., 1996; Fukushima et al., 1998; Bandoh et al., 1999; Goetzl et al., 1999; Ishii et al., 2000).
Functional Studies of LPA Receptors
The key observation leading to identification oflp A1 as encoding a LPA receptor was that overexpression of the receptor in the cortical cells from which it was cloned resulted in an increased percentage of rounded or neurite-retracted cells (Hecht et al., 1996). The ligand for this receptor was determined to be present in serum, used routinely for the growth of these cells, and based on heat stability, specific [3H]LPA binding to plasma membrane preparations and functional responses including AC inhibition, LPA was identified as a ligand (Hecht et al., 1996).
Additional reports provided further information regarding the responses mediated by LPA1(Table 1). Expression of the human ortholog (Edg2) caused increased LPA responsiveness in a serum-responsive element (SRE) reporter gene assay in human embryonic kidney 293 cells, increases in specific [3H]LPA binding to plasma membrane preparations in Chinese hamster ovary cells (An et al., 1997b), and in Jurkat T cells, increases in [Ca2+]i (An et al., 1998b). Human LPA1 heterologously expressed in yeast that have neither lp-related receptors nor endogenous responses to LPA also resulted in a dose-dependent response to LPA for activating the mitogen-activated protein (MAP) kinase pathway (Erickson et al., 1998).
Mammalian heterologous expression approaches were made possible through the identification of two mammalian cell lines, B103 (rat neuroblastoma) and RH7777 (rat hepatoma), that have undetectablelp A transcripts and that lack endogenous responses to LPA (Fukushima et al., 1998; Ishii et al., 2000). Cell lines heterologously expressing receptor proteins showed increased specific [3H]LPA binding to plasma membrane preparations and activation of G proteins as detected by GTPγS incorporation (Fukushima et al., 1998). They also became responsive to LPA as manifested by cell rounding, bromodeoxyuridine incorporation, SRE activation, and stress-fiber formation (Fukushima et al., 1998). In B103 cells expressing LPA1, LPA induced activation of phospholipase C (PLC) and MAP kinase, arachidonic acid release, and inhibition of AC (Ishii et al., 2000). These studies confirmed LPA1 identity and further demonstrated that a single LPA receptor could activate several distinct signaling pathways.
Several experiments have demonstrated thatlp A2 also encodes a multifunctional LPA receptor (Table 1). In initial reports, the human mutantlp A2 (Edg4) was expressed in Jurkat T cells, conferring LPA-specific responses in SRE activation and calcium mobilization assays (An et al., 1998a,b). Bandoh et al. (1999)reported that expression of human lp A2 in Sf9 insect and rat PC12 cells conferred [Ca2+]i increases and MAP kinase activation, respectively, whereas heterologous expression of murine lp A2 within murine B103 cells produced LPA-dependent cell rounding, activation of PLC and MAP kinase, arachidonic acid release, and inhibition of AC (Ishii et al., 2000). Differences in assay systems may alter outcomes as observed for increased cAMP formation in response to LPA in LPA2-expressing Sf9 cells, contrasting with the decrease that was observed in Edg4-expressing HTC4 cells (An et al., 1998b) or LPA2-expressing B103 cells (Ishii et al., 2000). Others reported that lp A2expression in RH7777 cells conferred LPA-dependent [Ca2+]i increases but had no effect on cAMP accumulation unlikelp A1-transfected cells where a decrease was observed (Im et al., 2000b).
A third multifunctional LPA receptor is encoded bylp A3, as demonstrated by three independent studies (Table 1). The human gene was expressed in Sf9 cells, resulting in LPA-dependent [Ca2+]iincreases and cAMP accumulation (similar to LPA2) (Bandoh et al., 1999). By comparison, the expression of the human receptor in RH7777 cells mediated LPA-dependent [Ca2+]i increases without cAMP accumulation (Im et al., 2000b). Mouse LPA3expressed in B103 cells mediated activation of PLC and MAP kinase, arachidonic acid release, and inhibition of AC but not cell rounding (Ishii et al., 2000).
These different responses mediated by the three LPA receptors, as well as the sensitivity of these responses to specific inhibitors such as PTX and Botulinum C3 toxin, suggest some differences in G protein-coupling (Figs. 2 and 4). Of the four primary classes of heterotrimeric G proteins, Gs, Gi/o, G12/13, and Gq, LPA receptors apparently couple to all but the Gstypes under physiological conditions. LPA stimulates cell proliferation through activation of tyrosine kinase and MAP kinase (Moolenaar et al., 1997). Gi/o-type proteins are the most likely candidates to mediate these effects of PTX sensitivity. The morphological responses to LPA (e.g., stress-fiber formation, cell rounding) are mediated primarily through Rho activation by the G12/13 proteins (Buhl et al., 1995). Rho activates Rho kinases (e.g., ROCK), which in turn phosphorylate cytoskeletal proteins. A specific inhibitor of Rho kinases, Y-27632, is available and has been shown to block morphological responses to LPA (Uehata et al., 1997). PLC activation, which leads to the production of two major classes of second messengers, diacylglycerol and inositol triphosphate, are mediated by the α-subunits of Gq-type proteins (these include Gq, G11, G14, and G15/16) and/or the βγ-subunits of Gi/o proteins (Exton, 1997). Most studies indicate that the LPA1 receptor can couple to the Gi/o, G12/13and Gq families (Hecht et al., 1996; An et al., 1997a,b; Fukushima et al., 1998; Ishii et al., 2000). LPA2 also can couple to the Gi/o, G12/13, and Gq families (An et al., 1998a,b; Bandoh et al., 1999; Im et al., 2000b; Ishii et al., 2000). Similar experiments indicate that LPA3 can couple to the Gi/o and Gq families (Bandoh et al., 1999; Im et al., 2000b; Ishii et al., 2000). Interestingly, it appears that LPA3 does not couple efficiently with G12/13, based on the lack of cell rounding in B103 cells expressing this receptor (Ishii et al., 2000).
Expression Patterns of lpA Genes
A major locus of lp A1 expression is within the embryonic cerebral cortex, where it is enriched in the ventricular zone, the zone of neurogenesis (Hecht et al., 1996; Chun, 1999; Dubin et al., 1999; Fukushima et al., 2000).lp A1 is also expressed in the adult mouse brain (Fig. 5), where in situ hybridization and Northern blot analyses demonstrate expression in oligodendrocytes, as well as Schwann cells of the peripheral nervous system; these are myelinating cells of the nervous system (Allard et al., 1998; Weiner et al., 1998; Chun, 1999; Weiner and Chun, 1999). Based on Northern blot analysis in adult mouse organs,lp A1 is also expressed in many other tissues, including testes, lung, heart, intestine, spleen, kidney, thymus, and stomach (Fig. 5). No expression was detectable in liver. Human lp A1 is similarly expressed in many adult organs, including brain, heart, colon, small intestine, placenta, prostate, ovary, pancreas, testes, spleen, skeletal muscle, and kidney (An et al., 1998a). Little or no expression was apparent in liver, lung, thymus, or peripheral blood leukocytes.
Mouse lp A2 is expressed most abundantly in testes, kidney, and embryonic brain (Fig. 5; Contos and Chun, 2000). Other organs also express the transcript, including heart, lung, spleen, thymus, stomach, and adult brain, and several have little or no expression, including liver, small intestine, and skeletal muscle (Contos and Chun, 2000). Human lp A2 is expressed most abundantly in testes and peripheral blood leukocytes with less expression in pancreas, spleen, thymus, and prostate (An et al., 1998a). Little or no expression was detectable in heart, brain, placenta, lung, liver, skeletal muscle, kidney, ovary, small intestine, or colon.
Mouse lp A3, likelp A2, is expressed most abundantly in testes, kidney, and lung, with moderate levels in small intestine, and low levels in heart, stomach, spleen, and adult and perinatal brain (Fig. 5). Little or no expression was detectable in embryonic brain, liver, or thymus. Human lp A3 is expressed most abundantly in prostate, testes, pancreas, and heart, with moderate levels in lung and ovary (Bandoh et al., 1999; Im et al., 2000b). No expression was detectable in brain, placenta, liver, skeletal muscle, kidney, spleen, thymus, small intestine, colon, or peripheral blood leukocytes.
lpA Structure
The first lp A gene characterized at the genomic level was lp A1 (Contos and Chun, 1998). The primary transcript (represented by thevzg-1 cDNA clone) is divided among four exons, with the open reading frame (ORF) distributed over the last three exons (Fig.6). Introns are situated 5′ to the coding region for transmembrane domain I (TMD I) and within the coding region for TMD VI. This finding was unexpected because the majority of GPCR gene ORFs, including the evolutionarily related genes for a S1P receptor, lp B1/edg1, and a cannabinoid receptor, Cnr1, have uninterrupted ORFs. The presence of an intron in the coding region for TMD VI indicates that it was inserted into the gene after it diverged from thelp B genes. Interestingly, a cDNA clone variant (mrec1.3) has a completely divergent 5′ sequence fromlp A. This sequence divergence is exactly at the boundary between exons 2 and 3 and was determined to be due to use of an alternative primary exon, located between exons 2 and 3. The coding region of the mrec variant starts at the second ATG of thelp A ORF, resulting in a protein with 18 fewer amino acids (Fig. 3, beginning with the MNE… ). The function of these two different isoforms of LPA1 remains unclear. Recent experiments indicate that the two transcript forms are produced from alternative promoter usage rather than alternative splicing (J. J. A. Contos and J. Chun, unpublished observation). The human gene has a 4-exon structure similar to the mouse gene (Allard et al., 1999). However, no human counterpart to the mrec exon has been identified in over 150 cDNA clones analyzed.
Both mouse (Fig. 6) and human lp A2 genes are divided among three exons (Contos and Chun, 2000). The structure is very similar to that of the mrec variant oflp A1. Both have start and stop sites in the second and third exons, respectively, and introns located just upstream of the start codon and within the coding region for TMD VI. In both mouse and human, two transcript sizes are evident from Northern blot analysis (Fig. 5; An et al., 1998a). In human, these are ∼1.8 kb (found primarily in testes, prostate, and pancreas) and ∼10 kb (found in leukocytes, spleen, and thymus), whereas in mouse they are ∼3 kb (found in all expressing tissues) and ∼7 kb (found in kidney, testes, and embryonic brain). Although the smaller transcript sizes are expected from the gene structures, the function of the larger transcript is not known.
Analysis of the mouse lp A3 genomic clone (J. J. A. Contos and J. Chun, submitted for publication) indicates that the gene is also divided among three exons in a structure very similar to lp A2 (Fig. 6). Introns are located just upstream of the start codon and within the middle of the coding region for TMD VI. Reverse transcription-PCR analysis with primers within exons 1, 2, and 3 indicates that the three exons were spliced in all tissues that were shown to express the transcript by Northern blot analysis (Fig. 5).
lpA Chromosomal Location
Chromosomal location of each mouse LPAreceptor was determined by linkage analysis. Thelp A1 gene was localized to proximal chromosome 4 at a location indistinguishable from the vacillans gene (vc) (Contos and Chun, 1998). These results are in disagreement with localization for the lp A1isoform mrec1.3 where the gene was placed at distal chromosome 4 (Macrae et al., 1996). The contrasting results might be explained by the unusual finding that exon 4 is duplicated on chromosome 6 in Mus spretus (Contos and Chun, 1998) and usage of different lp A1 regions in segregation analyses. Vacillans refers to the gene(s) mutated and responsible for a phenotype characterized in the 1950s (Sirlin, 1956). Although the segregation pattern of vc has been determined, the genes responsible have not been characterized. Thus, mutations inlp A1 might be related to the vcphenotype. Vacillans was named because the homozygous mutant (vc/vc) mice would “vacillate” or waddle when walking, indicating problems with motor control. These mice also displayed violent tremors, less aggressive behaviors, smaller overall sizes, approximately half-normal muscular strength, a mortality rate of 50% by weaning, and delayed male sexual maturity. Some of the phenotypes might be explained by problems in brain development and function, peripheral nerve conduction, and testes development. The expression pattern of lp A1 in embryonic brain, myelinating cells (i.e., oligodendrocytes), and testes, suggests that mutations in lp A1 might be responsible for vc. Unfortunately, neither the vc mice nor their DNA remain, making further analyses impossible. Targeted deletion of lp A1 in mice shows cellular and growth defects that overlap with some of these vc phenotypes (Contos et al., 2000).
Using backcross analysis, mouse lp A2 was localized to central chromosome 8 at a location indistinguishable from the myodystrophy (myd) gene and very close to the “kidney anemia testes” (kat) gene (Contos and Chun, 2000). The expression pattern of lp A2 supports a relationship between lp A2 andkat but not to myd. The kat phenotype includes polycystic kidney disease, anemia, and male sterility (Janaswami et al., 1997). However, no mutations inlp A2 exons could be found inkat/kat mouse genomic DNA (J. J. A. Contos, unpublished observation). In segregation analyses,kat localizes between DMit128 andDMit129 markers, whereas lp A2localizes outside of this interval. Thus, mutations inlp A2 are unlikely to be related to thekat phenotype.
Mouse lp A3 was localized to the middle of chromosome 3 in the region of the varitint waddler (va) gene (J. J. A. Contos and J. Chun, submitted for publication). Interestingly, this va phenotype has several features similar to the vc phenotype. Heterozygous (va/+) mice have a tinted coat color in various regions (hence the “varitint” name) and moved with a “duck-like” walk (hence the “waddler” name), similar to the vacillation ofvc/vc mice (Cloudman and Bunker, 1945). They are deaf, react violently when disturbed, and run in circles when excited. The homozygous mutation (va/va) resulted in approximately 80% lethality. Because lp A3expression has not been examined in areas likely defective inva mice and possible mutations inlp A3 have not been analyzed inva/va genomic DNAs,lp A3 remains a possible candidate forva.
Human lp A1 was localized to chromosome 9q31.3-32 based on analyses of the presence of the human gene in human x rodent somatic cell hybrid panels and yeast artificial chromosomes mapped to this region (Allard et al., 1999). Humanlp A2 was identified on genomic clones that were localized to chromosome 19p12 (Contos and Chun, 2000). Mutations in the gene have not been analyzed for genetically inherited disorders that map to this region. However, one possible disorder that may be related to lp A2 mutations is a congenital myeloid leukemia that results from a translocation to this region: t(11;19) (q23;p12-13.1) (Huret et al., 1993). Should this translocation disrupt lp A2 expression or function, misregulation of myeloid cell proliferation might result. No information has been published on the chromosomal location of humanlp A3. However, it appears to be located on chromosome 1, probably at 1p31.2, which is the only area of chromosome 1 syntenic to mouse chromosome 3 (J. J. A. Contos and J. Chun, submitted for publication).
Potential Role of lpA2 Mutations in Ovarian Cancer
Several lines of evidence suggest that LPA signaling may have a role in the progression of ovarian cancer. LPA is known to be an “ovarian cancer activating factor” in ascites fluid from ovarian cancer patients (Xu et al., 1995b). Elevated levels of ascites LPA are present both at early and late stages in ovarian cancer; control subject ascites has lower LPA concentrations (Xu et al., 1995a;Westermann et al., 1998). LPA activates ovarian cancer cell lines (OCC) by increasing [Ca2+]i and stimulating proliferation; this effect was not observed in normal ovarian surface epithelial cells (OSE) (Xu et al., 1995a). LPA also acts as a survival factor for OCC because it antagonizes the programmed cell death effect of the primary chemotherapeutic agent used to treat the disease (Frankel and Mills, 1996). LPA stimulates OCC, but not OSE, to secrete urokinase plasminogen activator, a protein that contributes to metastasis and whose concentration in ascites is inversely correlated with ovarian cancer prognosis (Pustilnik et al., 1999). The source of LPA in ovarian cancer ascites fluid is unclear. Potential intraperitoneal sources include macrophages, mesothelial cells, or ovarian cancer cells themselves (Westermann et al., 1998).
The expression of lp A genes in OCC and OSE has been investigated. Independent studies demonstrated thatlp A2 has high expression levels in OCC and low expression levels in normal OSE, whereaslp A1 has low or no expression levels both in OCC and normal OSE (Furui et al., 1999; Goetzl et al., 1999;Pustilnik et al., 1999). Although expression oflp A3 is not explicitly shown, it was mentioned that its levels were also elevated in ovarian cancer cells (Pustilnik et al., 1999). These results suggest that LPA2 and possibly LPA3 are involved in mediating the LPA proliferation/transformation signals in ovarian cancer ascites, whereas LPA1 is not. In support of these hypotheses is the finding that stimulation of LPA2 using an LPA2-specific antibody/phorbol ester combination resulted in proliferation and SRE activation in OCC but not in OSE (Goetzl et al., 1999). In contrast, overexpression of lp A1 in OCC induces apoptosis and anoikis, the opposite effects of what would be expected if LPA promotes cancer progression (Furui et al., 1999). Thus, it appears that LPA2 could transduce LPA signals from ascites to susceptible cells during oncogenesis, and that mutations in lp A2 could cause the transcript and/or protein to be overexpressed in OCC or cause the protein to be constitutively activated.
The first-reported human Edg4 cDNA clone was derived from an ovarian tumor library (An et al., 1998a) and differed from humanlp A2 sequences (Contos and Chun, 2000). The predicted Edg4 protein product was 31 amino acids longer at its C terminus relative to the predicted protein product of mouselp A2 cDNA and genomic sequences (Fig. 3). Further analyses of other human genomic and EST sequences revealed that the extra 31 amino acids were specific to the Edg4 cDNA clone and could be explained by a guanine nucleotide deletion in the fourth-to-last codon (Contos and Chun, 2000). The extra 31 amino acids in the mutant LPA2 protein may alter normal LPA2 coupling with G proteins and/or related regulatory proteins such as GPCR receptor kinases, β-arrestins, or internalization proteins. In addition to the guanine deletion in the Edg4 ovarian tumor cDNA, there are also many sequence variations in the 3′ untranslated regions of multiple ESTs (Contos and Chun, 2000). Such variations might affect message stability. A more comprehensive study oflp A2 mutations and transcript levels in multiple ovarian neoplasms could clarify these issues.
Future Directions
Some of the most exciting aspects of LPA receptor studies have moved from receptor identification to determination of gene functions in normal biological and pathological processes. Targeted deletion of each lp A gene in mice will help to identify in vivo roles of LPA signaling, and initial studies indicate nonredundant and essential roles for signaling by a single LPA receptor (Contos et al., 2000). Receptor subtype-specific agonists and antagonists will be powerful research tools as well as potential clinical drugs, and although not currently available, it is likely that such reagents are on the horizon. Receptor-based studies, as well as those determining how mutations in lp Agenes might contribute to human genetic disorders and to other pathological processes such as cancer, will likely provide new insights on the roles of this simple lipid in the near future.
Acknowledgments
We thank Casey Cox for copyediting the manuscript.
Footnotes
- Received July 14, 2000.
- Accepted September 20, 2000.
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Send reprint requests to: Dr. Jerold Chun, Department of Pharmacology, School of Medicine, University of California, San Diego, 9500 Gilman Dr., La Jolla, CA. E-mail: jchun{at}ucsd.edu
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↵1 These authors contributed equally to this work.
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This work was supported by research grants from the National Institute of Mental Health (to J.J.A.C., J.C.) and the Uehara Memorial Foundation (to I.I.), and a sponsored research agreement with Allelix Biopharmaceuticals (to J.C.).
Abbreviations
- LPA
- lysophosphatidic acid
- LP
- lysophospholipid
- S1P
- sphingosine-1-phosphate
- SPC
- sphingosylphosphorylcholine
- GPCR
- G protein-coupled receptor
- AC
- adenylyl cyclase
- PTX
- pertussis toxin
- PCR
- polymerase chain reaction
- EST
- expressed sequence tag
- MAP kinase
- mitogen-activated protein kinase
- OCC
- ovarian cancer cell lines
- ORF
- open reading frame
- OSE
- ovarian surface epithelial cells
- PLC
- phospholipase C
- SRE
- serum-responsive element
- TMD
- transmembrane domain
- kb
- kilobases
- The American Society for Pharmacology and Experimental Therapeutics