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HEMATOPOIESIS
From the Institute for Hematology, Erasmus University
Rotterdam, The Netherlands; and Department of Experimental Medicine and
Biochemical Sciences, University of Rome "Tor Vergata," Rome,
Italy.
Cb2 is a novel protooncogene encoding the peripheral
cannabinoid receptor. Previous studies demonstrated that 2 distinct
noncoding first exons exist: exon-1A and exon-1B, which both splice to
protein-coding exon-2. We demonstrate that in retrovirally induced
murine myeloid leukemia cells with proviral insertion in
Cb2, exon-1B/exon-2 Cb2 messenger RNA levels
have been increased, resulting in high receptor numbers. In myeloid
leukemia cells without virus insertion in this locus, low levels of
only exon-1A/exon-2 Cb2 transcripts were present and
receptors could not be detected. To elucidate the function of Cb2 in
myeloid leukemia cells, a set of in vitro experiments was carried out
using 32D/G-CSF-R (granulocyte colony-stimulating factor receptor)
cells transfected with exon-1B/exon-2 Cb2 complementary DNA
and a myeloid cell line carrying a virus insertion in Cb2 (ie, NFS 78). We demonstrate that a major function of the Cb2 receptor
is stimulation of migration as determined in a transwell assay.
Exposure of Cb2-expressing cells to different cannabinoids showed that
the true ligand for Cb2 is 2-arachidonoylglycerol (2-AG), which may act
as chemoatractant and as a chemokinetic agent. Furthermore, we observed
a significant synergistic activity between 2-AG and interleukin-3 or
G-CSF, suggesting cross-talk between the different receptor systems.
Radioactive-ligand binding studies revealed significant numbers of Cb2
receptors in normal spleen. Transwell experiments carried out with
normal mouse spleen cells showed 2-AG-induced migration of B220-,
CD19-, immunoglobulin M-, and immunoglobulin D-expressing B
lymphocytes. Our study demonstrates that a major function of Cb2
receptor expressed on myeloid leukemia cells or normal splenocytes is
stimulation of migration.
(Blood. 2002;99:2786-2793) Two distinct cannabinoid receptors have previously
been identified: the central1 (Cb1) and the peripheral
(Cb2) cannabinoid receptor.2 In retrovirally induced
murine leukemia, proviral insertions frequently occur in the gene
encoding Cb2, suggesting that the peripheral
cannabinoid receptor is an oncoprotein.3,4 The cannabinoid
receptors belong to the superfamily of 7-transmembrane G
protein-coupled receptors (GPCRs). Several GPCRs have been shown to be
involved in cell growth and oncogenesis as the result of aberrant
expression.5-7 Examples of GPCRs with transforming ability are the GPCRs have been related to many functions, including cell
proliferation, maturation, survival, apoptosis, or
migration.6,13,14 In the present study, we investigated
the function of the peripheral cannabinoid receptor when overexpressed
on myeloid cells (ie, 32D/G-CSF-R [granulocyte colony-stimulating
factor receptor]) in which we overexpressed exon-1B/exon-2
Cb2 splice variant and a myeloid leukemia cell line
containing a virus insertion in the Cb2 locus, NFS 78. We also wished
to determine which of the large panel of Cb2 ligands that have been
identified previously is the true agonist of the receptor. We
investigated the effects of natural ( Cell lines
Ligands and cannabinoid ligands
Cb2 expression constructs and transfection of 32D/G-CSF-R cells Cb2 exon-1B plus exon-2, which was hemagglutinin (HA)-tagged at the 5' end (EcoRI/NcoI), was cloned as HindIII/BamHI fragment into HindIII/BglII sites of pLNCX. The expression construct was transfected into 32D/G-CSF-R by electroporation (230V, 100 microfarads, and 1000 milliseconds). Following gene transfer, cells were cultured in RPMI 1640 medium supplemented as above for 48 hours and then selected in neomycin at concentrations of 0.8 mg/mL. Neomycin-resistant clones were expanded. To study Cb2 mRNA expression, ribonuclease (RNase) protection analysis was applied. Because mouse Cb2-specific antibodies are not yet available and HA antibodies are not capable of detecting HA-Cb2, Cb2 protein expression was analyzed by ligand binding (see below).RNase protection analysis RNase protection analysis was performed as described previously.27 Total cellular RNA was prepared from kidney, heart, spleen, and thymus by homogenizing tissue cells in 4 M guanidium thiocyanate, followed by phenol-chloroform extraction and isopropanol precipitation.28 RNA from NFS cell lines and 32D/G-CSF-R-transfected cells was isolated using 4 M guanidium thiocyanate or Trizol Reagent (Life Technologies). The RNA samples were subjected to an RNase protection assay, essentially as described by the supplier (Promega, Leiden, The Netherlands). A 249-base pair (bp) fragment (bp 147 to bp +102 of Cb2 complementary DNA
[cDNA], probe P) (Figure 1A) was cloned
into a pBluescript II SK+ vector and linearized with
HindIII. A radiolabeled GAPDH RNA fragment was
used as a control.29
Membrane preparation and [3H]CP55940 binding assays Frozen cell and tissue pellets were kept at80°C until use.
Pellets were thawed and suspended in assay buffer (50 mM Tris-HCl [pH
7.0], 1 mM ethylenediaminetetraacetic acid, 3 mM MgCl2,
100 µM phenylmethylsulfonyl fluoride [pH 7.4] containing 0.1%
bovine serum albumin [Serva, Heidelberg, Germany]), and
membrane suspensions were homogenized and centrifuged at
10 000g for 10 minutes (4°C). Pellets were then
resuspended in 5 mL in assay buffer, homogenized using a
Potter-Elvejhem homogenizer, and resuspended in assay buffer at a final
membrane concentration equivalent to 106 cells per
milliliter. For binding experiments, 160 µL membrane suspension
(106 cells/mL) was incubated in 96-well plates (flat-bottom
plates, Greiner) with 20 µL [3H]CP55940 (DuPont-New
England Nuclear) in concentrations ranging from 0.2 nM to 1.2 nM and 20 µL assay buffer for total binding or assay buffer containing
10 5 M nonlabeled CP55940 to assess nonspecific binding.
Mixtures (200 µL final volume) were incubated at 30°C for 50 minutes, after which suspensions were filtrated over Unifilter GF/B
plates using a Filtermate-196 Harvester (Packard) and washed twice for
5 seconds with 200 µL ice-cold washing buffer (50 mM Tris-HCl [pH
7.0] containing 0.25% bovine serum albumin). Filtration plates were
sealed at the bottom, 25 µL scintillation fluid (Microscint-O,
Packard) was added per well, and radioactivity was counted in a
TopCount scintillation counter (Canberra Packard). Saturation curves
produced identical affinities for [3H]CP55940 (affinity
dissociation constant [Kd] ranged from 0.25 to
0.5 nM). Saturation plots were constructed by plotting specific binding
(ie, total binding minus nonspecific binding) against label
concentration, ranging from 0.2 nM to 1.2 nM, after which nonlinear
curve fitting was done to estimate Bmax and affinity. In
parallel, Scatchard plots were constructed by plotting the ratio-specific binding over free-label concentration against specific binding. Cb2 binding sites with spleen cells or thymocytes (Figure 7B) were assessed in triplicate using one radioligand
concentration of CP55940 (1 nM). Nonspecific binding was determined in
the presence of excess nonradioactive CP55940 (106M), and
specific binding was expressed as femtomoles per 106 cells
(Figure 7C).
Migration assay Migration assays were performed using 6.5 mm-diameter transwells with 5 µm pore size (Corning Costar, Amsterdam, The Netherlands). The cells used for the migration assay were NFS 58, 61 and 78 cells, transfected 32D/G-CSF-R cells, and spleen and thymus cells from male FVB mice. Mice were killed by inhalation of CO2. Spleen and thymus were isolated immediately and placed on RPMI 1640 medium. Single-cell suspension was prepared using 70-µm nylon cell strainer (Falcon, NJ). For migration assay, 1 × 105 or 2 × 105 cells were washed twice with Hanks balanced salt solution medium, resuspended in 100 µL migration medium (Iscoves modified Dulbecco medium plus 0.5% bovine serum albumin), and placed in the upper chamber of the transwells with or without presence of ligand. In the lower chamber, 600 µL migration medium with or without ligand was placed. After 4 hours' incubation at 37°C and 5% CO2, the upper chamber was removed and the number of migrated cells was determined using a CASY1/TTC cell counter (Schärfe System, Germany).Flow cytometric analysis Spleen cells that migrated to the lower chamber in the migration assay were immunophenotyped using a FACSCalibur flow cytometer (Becton Dickinson, Mountain View, CA). The following rat monoclonal antibodies were used in indirect immunofluorescence assays: RA3-6B2 (anti-B220/CD45R), Ter119 (LY-76), 59-AD2.2 (anti-Thy-1), and KT3 (anti-CD3). A fluorescein isothiocyanate-conjugated goat anti-rat immunoglobulin (Ig) (Nordic Immunological Labs, Tilburg, The Netherlands) was used as a second-step reagent. Immunophenotyping with double or triple labeling was performed combining the mentioned antibodies with allophycocyanin-conjugated anti-B220/CD45R (RA3-6B2), phycoerythrin-conjugated anti-IgD (Southern Biotechnology, Birmingham, AL), anti-CD19 (1D3), and anti-CD11c (HL3), as well as biotinylated anti-IgM (II/41), using streptavidin-allophycocyanin as a second step (Pharmingen, San Diego, CA).
Cb2 expression analysis in myeloid leukemic cell lines The protein-coding region for the peripheral cannabinoid receptor is located on exon-2 of the Cb2 gene (Figure 1A). Two distinct Cb2 splice variants have been identified, which both comprise the Cb2 receptor coding exon but contain different nonprotein-coding first exons: exon-1A or exon-1B (Figure 1A). To determine which splice variant is present in myeloid cell lines, RNase protection was performed using a 249-bp polymerase chain reaction product (probe P) overlapping exon-1B (101 nucleotides) and exon-2 (148 nucleotides) (Figure 1A). A protected band of 249 nucleotides corresponding to exon-1B plus exon-2 Cb2 mRNA was identified in the myeloid cell line NFS 78 (Figure 1B), which contains a retroviral insertion in Cb2, whereas a 148 nucleotide exon-2-protected fragment was identified in the other myeloid cell lines (Figure 1B). As demonstrated previously, this latter protected fragment represents exon-1A/exon-2 Cb2 transcript.3,27 Ligand binding studies using [3H]CP55940 and Scatchard plot analysis revealed the presence of significant numbers of cannabinoid binding sites on NFS 78 cells, whereas receptors were not measurable on the other IL-3-dependent myeloid cell lines (Figure 1C).The endocannabinoid 2-AG is the true ligand for Cb2 receptor and stimulates migration of Cb2-expressing myeloid cells Next, we wished to determine the function of the peripheral cannabinoid receptor when overexpressed in myeloid cells and investigate which of the large panel of molecules capable of binding is the true ligand for Cb2. For this purpose we used the Cb2-overexpressing myeloid cell line NFS 78 as well as 2 clones of the 32D/G-CSF-R cell line in which we introduced exon-1B/exon-2 Cb2 cDNA. High exon-1B/exon-2 Cb2 mRNA expression was demonstrated by RNase protection (Figure 2A), and ligand binding studies demonstrated excess of [3H]CP55940 binding sites on exon-1B/exon-2 Cb2-transfected cells (Figure 2B). No exon-1B/exon-2 Cb2 mRNA or ligand binding sites were detected in the vector control 32D/G-CSF-R cells (Figure 2).
Because G protein-coupled receptors may function in cell mobility, we
investigated in vitro migration in transwell assays. The following
cannabinoid ligands were added to the lower chamber to test their
capacity to induce chemotactic migration (1 µM): AEA, 2-AG, PEA,
POEA, CP55940,
2-AG stimulates chemotaxis as well as chemokinesis of Cb2-expressing myeloid cells To investigate whether 2-AG is a chemokinetic as well as a chemotactic agent, in vitro migration experiments were carried out with 2-AG added to the lower chamber, the upper chamber, or both. When 2-AG was added to the upper and lower chamber simultaneously, approximately 50% migration was observed as compared with the chemotactic experiment (ie, with 2-AG added to the lower well only) (Figure 4). No cells migrated when 2-AG was added to the upper well only. In comparison, 32D/G-CSF-R/Cb2 cells, which express the CXC chemokine receptor 4 (CXCR4) endogenously, migrated when the CXCR4 ligand SDF-1 was added to the lower chamber. However, no chemokinetic mobility was observed when SDF-1 was added to both
chambers (Figure 4).
Natural and synthetic cannabinoids inhibit 2-AG-induced migration, whereas endocannabinoids have no effect Because the endocannabinoids (AEA, PEA, POEA) as well as the natural ( 8-THC, 9-THC) and the synthetic
cannabinoid ligands (CP55940, WIN 55212-2) are capable of binding to
the peripheral cannabinoid receptor, we wondered whether these
compounds could either synergize with 2-AG or antagonize the effect of
this ligand in a migration assay. The synthetic cannabinoids CP55940
and WIN 55212-2 as well as 8-THC and
9-THC completely abolished 2-AG-induced
chemoattraction of Cb2-transfected 32D/G-CSF-R cells when
added either to the lower (Figure 5A) or the upper chamber in a transwell assay (data not shown). On the other
hand, AEA, PEA, and POEA did not affect 2-AG-induced chemoattraction (Student t test, P > .05) of cells when either
added to the lower (Figure 5B) or to the upper chamber in a migration
assay (not shown).
Effects of 2-AG in combination with IL-3 or G-CSF on migration of Cb2-expressing cells To study whether Cb2 receptor ligands may synergize with other ligands that can activate 32D/G-CSF-R cells, we carried out migration experiments using 2-AG in combination with IL-3 or G-CSF. No migration was observed when 32D/G-CSF-R/Cb2 cells were exposed to IL-3 or G-CSF alone in a transwell assay. However, addition of 2-AG with IL-3 or G-CSF showed a significant increase in the migration rate of these cells as compared with experiments using 2-AG as a single agent (Figure 6). The same effect was observed when NFS 78 cells were exposed to 2-AG and IL-3 (data not shown).
Distinct Cb2 mRNA splice variants and protein levels in mouse spleen and thymus The functional assays carried out so far were performed with cells that overexpress Cb2 receptor. Before elucidating whether naturally expressing Cb2 cells migrate following 2-AG exposure as well, we first investigated which hematopoietic organs express Cb2. RNase protection analysis was carried out on thymus and spleen mRNA using probe P (Figure 1A). A protected band of 249 nucleotides, corresponding to exon-1B plus exon-2 Cb2 mRNA, was identified in spleen (Figure 7A), whereas a 148 nucleotide exon-2-protected fragment, representing exon-1A/exon-2 Cb2 transcript, was identified in spleen and thymus (Figure 7A). Cb2 mRNA was not detectable in the other tissues investigated27 (Figure 7A). To study the presence of Cb2 binding sites in spleen and thymus, a binding assay was carried out using a saturated concentration of 1 nM [3H]CP55940 (determined on NFS 78 [Figure 1C]). The experiment in Figure 7B demonstrates that [3H]CP55940 binding is observed in spleen and not in thymus of normal FVB mice, which is in agreement with previous studies.30,31
Migration of Cb2-expressing spleen cells following 2-AG stimulation To investigate whether naturally expressing Cb2 cells migrate following 2-AG exposure as well, spleen cells from FVB mice were studied using a transwell assay. A titration experiment showed optimal migration of spleen cells in the presence of 300 nM 2-AG (data not shown). Moreover, this migration could be blocked by addition of Cb2-specific antagonist to the upper well but not by addition of Cb1-specific antagonist (Figure 7C). No significant migration was evident of thymocytes in transwells (data not shown). Immunophenotyping by flow cytometric analysis of the 2-AG-induced migrated spleen cells compared with spontaneously migrated spleen cells revealed that the cells were B220+. Double staining revealed that these B220+ cells expressed CD19, IgM, and IgD (Figure 7D). In addition, these cells were CD11c, indicating that the
spleen-migrated cells were B lymphocytes and not
B220+/CD11c+ dentritic cells (Figure
7D).
In the study presented here, we demonstrate that 2 distinct Cb2 mRNA splice variants exist in the mouse, each composed of the same protein-encoding exon-2 but with a different nonprotein-coding first exon. In most myeloid leukemia cell lines Cb2 exon-1A/exon-2 is expressed, which correlates with low protein expression. On the other hand, in mouse leukemia NFS 78, retroviral insertion has occurred 5' of exon-1B,3,32 resulting in the expression of high levels of Cb2 exon-1B/exon-2 mRNA and the appearance of Cb2 proteins on the cell surface. Cb2 receptors are also present on normal spleen cells, which express both Cb2 splice variants: exon-1A/exon-2 and exon-1B/exon-2. On the other hand, thymocytes only express Cb2 exon-1A/exon-2 splice variants, which are not accompanied by the presence of detectable numbers of ligand binding sites. These data suggest that in the cells studied here, Cb2 protein may be translated from exon-1B/exon-2 transcripts rather than from exon1A/exon2 mRNAs. These results may be explained by a regulatory mechanism of translation involving the noncoding first exons of Cb2. Although several mechanisms of translational control involving noncoding mRNA have been described,33-36 the function of the 2 first exons in Cb2 is currently unknown. Whether and how these nonprotein-coding exons may regulate protein expression is subject to future investigations. Oncogenic transformation by GPCRs may be caused either by structural
alteration of the receptor itself or by deregulated presentation of the
ligands.8,37,38 We previously demonstrated that retroviral insertion in the Cb2 locus occurs frequently in myeloid
leukemias in mice.3,32 The data presented here suggest
that proviral insertion in Cb2 in myeloid leukemia cells may
result in the selective expression of particular splice variants and
overexpression of the peripheral cannabinoid receptor. GPCRs have been
related to a variety of cellular functions, including cell
proliferation, differentiation, survival, and
migration.39,40 To study the role of the peripheral
cannabinoid receptor when overexpressed on myeloid cells, we
investigated the effects of cannabinoid ligands on the myeloid cell
line NFS 78 and on 32D/G-CSF-R cells transfected with the
Cb2 exon-1B/exon-2 splice variant. We demonstrate that stimulation of Cb2-overexpressing cells by its potent agonist 2-AG
induces migration in vitro at nanomolar concentrations. Given the role
of Cb2 receptor in migration in vitro, we investigated whether 2-AG may
act as a chemotactic as well as a chemokinetic agent. In contrast to
SDF-1 We previously demonstrated that AEA is a potent inducer of proliferation in synergy with IL-3, granulocyte-macrophage CSF, or G-CSF.27 However, we and other investigators suggested that although AEA may be an activator of Cb2, this fatty acid has also a nonreceptor-mediated stimulating effect.27,49-51 We could not detect an effect of 2-AG on survival or proliferation of Cb2-expressing cells (data not shown). However, this does not exclude the possibility that under different conditions or in combination with other cytokines this receptor may have an effect on these functions. In fact, synergy between cytokines and chemokines has been previously observed in proliferation, differentiation, and survival assays as well as in migration experiments.27,52-55 Our findings showing increased migration when cells were stimulated with 2-AG and IL-3 as well as 2-AG and G-CSF strengthen the idea to further investigate the role that 2-AG may have in combination with cytokines in proliferation, differentiation, or survival of leukemic progenitor cells. Several cannabinoid ligands from different origin (natural,
synthetic, and endogenous) have been proposed as the true cannabinoid ligands.19,20,22,56 In the present study we compared the effects of 2-AG with that of the other endocanabinoids (AEA, PEA, POEA), the natural cannabinoids (
We thank Dr R. Hendrix for excellent assistance during immunophenotyping of spleen-migrated cells and P. van Hennik for technical assistance in migration assays. We also thank Karola van Rooyen for preparation of the figures and Dr P. Casellas (Sanofi Recherche, Montpellier, France) for donation of the Cb1 and Cb2 receptor-specific antagonists SR141716 and SR144528, respectively.
Submitted April 10, 2001; accepted December 13, 2001.
Supported by the Dutch Cancer Foundation Koningin Wilhelmina Fonds, The Netherlands Organisation for Scientific Research (NWO), and the Royal Dutch Academy of Sciences (KNAW).
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Ruud Delwel, Institute for Hematology, Erasmus University Rotterdam, Dr Molewaterplein 50, 3015GE Rotterdam, The Netherlands; e-mail: delwel{at}hema.fgg.eur.nl.
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Top
Abstract
Introduction
) or nothing (
) on exon-1B/exon-2 Cb2-expressing
cells versus non-Cb2-expressing cells. Y-axis shows
percentage of migrated cells from an input of 2 × 105
cells. (E) Cb2-expressing 32D/G-CSF-R cells were exposed to
medium with or without 300 nM 2-AG added to the lower well; 100 nM
Cb1-specific antagonist, SR141716, Cb2-specific antagonist, SR144528,
or cells without antagonist as a control were placed on the upper well.
Y-axis shows percentage of migration from an input of
1 × 105 cells.
subunit of Gi, not by activating Gq or Gs.
Proc Natl Acad Sci U S A.
1997;94:14489-14494