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J Biol Chem, Vol. 274, Issue 36, 25594-25598, September 3, 1999
From the Arthritis Unit, Department of Medicine, Massachusetts
General Hospital and Harvard Medical School,
Charlestown, Massachusetts 02129
Leukotriene formation is initiated in myeloid
cells by an increase in intracellular calcium and translocation of
5-lipoxygenase from the cytoplasm to the nuclear envelope where it can
utilize arachidonic acid. Monocyte- macrophages and eosinophils
also express 15-lipoxygenase, which converts arachidonic acid to
15(S)-hydroxyeicosatetraenoic acid. Enhanced green
fluorescent 5-lipoxygenase (5-LO) and 15-lipoxygenase (15-LO) fusion
proteins were expressed in the cytoplasm of RAW 264.7 macrophages. Only
5-lipoxygenase translocated to the nuclear envelope after cell
stimulation, suggesting that differential subcellular
compartmentalization can regulate the generation of leukotrienes
versus 15(S)-hydroxyeicosatetraenoic acid in
cells that possess both lipoxygenases. A series of truncation mutants of 5-LO were created to identify putative targeting domains; none of
these mutants localized to the nuclear envelope. The lack of targeting
of 15-LO was then exploited to search for specific targeting motifs in
5-LO, by creating 5-LO/15-LO chimeric molecules. The only chimera that
could sustain nuclear envelope translocation was one which involved
replacement of the N-terminal 237 amino acids with the corresponding
segment of 15-LO. Significantly, no discrete targeting domain could be
identified in 5-LO, suggesting that sequences throughout the molecule
are required for nuclear envelope localization.
Macrophages and eosinophils express two related lipoxygenase
(LO)1 enzymes capable of
utilizing arachidonic acid as a substrate (1-7). 5-LO initiates the
generation of biologically active leukotrienes (7-9), whereas 15-LO
generates 15-hydroxyeicosatetraenoic acid (10). 5-LO and 15-LO are
cytoplasmic enzymes in resting cells. They are similar in size (674 and
662 aa, respectively), share 61% amino acid similarity (11, 12), and
both co-ordinate non-heme iron at the active site (13-15) by means of
conserved internal histidines and a C-terminal isoleucine. Modeling
studies reveal that the binding site for arachidonic acid is smaller in
15-LO, resulting in insertion of oxygen at carbon-15 instead of
carbon-5 (16). The profile of eicosanoid products generated by these cells depends on how 5-LO and 15-LO are differentially regulated to use
arachidonic acid, a process which is not understood.
Leukotriene biosynthetic enzymes assemble on the nuclear envelope
following cell stimulation. cPLA2 translocates to the
nuclear envelope (17, 18) where it liberates arachidonic acid from membrane phospholipids. 5-LO also translocates to the nuclear envelope
(18-20) and acts on arachidonic acid in sequential steps to generate
5-hydroperoxyeicosatetraenoic acid and then LTA4 (21). The
conversion of arachidonic acid to LTA4 requires the
expression of FLAP, a 17-kDa nuclear envelope protein critical to 5-LO
activity (21, 22) but not necessarily to translocation (20). FLAP probably presents arachidonic acid to 5-LO (23) or restricts the
diffusion of arachidonic acid within cellular membranes.
LTB4 and LTC4 are then formed by the action of
the enzymes LTA4 hydrolase (24) and LTC4
synthase (25, 26), respectively. The mechanisms underlying assembly of
leukotriene biosynthetic enzymes on the nuclear envelope are not understood.
The functions of 15-LO are still being elucidated. 15-LO has the
capacity to utilize phospholipids as a substrate, oxidizing arachidonic
acid and linoleic acid esterified at the SN2 position (27, 28). The
direct oxidation of intracellular membranes may be an intermediate step
in membrane degradation and turnover in the differentiation of certain
cells (27-29). It has also been suggested that 15-LO plays a role in
the initiation of atherogenesis by oxidizing fatty acids esterified in
cholesterol esters (30-32). The production of
15-hydroxyeicosatetraenoic acid in hematopoietic cells might require
the liberation of arachidonic acid from phospholipids prior to
oxidation. 15-LO has been reported to associate with membranes after
stimulation of hematopoietic cells (5), but it is not known whether it
can be co-localized with the leukotriene forming enzymes on the nuclear envelope.
The assembly of multiprotein complexes on specific membrane boundaries
is now recognized as a process of general importance. It is a feature
of signal transduction systems such as cytokine receptor complexes on
the plasma membrane and enzyme systems such as the NADPH oxidase
complex of activated phagocytes, and it may regulate leukotriene
formation at the nuclear envelope. A growing number of peptide motifs
are being identified which mediate precise targeting of the protein
components (33). These include motifs which mediate direct binding to
phospholipids such as PH domains, or motifs which mediate
protein-protein interactions such as SH2 and SH3 domains. Whereas
enzyme activity is critically dependent on the tertiary structure of a
protein, targeting motifs are modular in nature. Both 5-LO and 15-LO
have a proline-rich sequence that resembles an SH3 binding domain
located 95 aa from the C-terminus (11, 12, 34). 15-LO has a second
proline-rich sequence between aa 326-338, and it is possible that the
two enzymes have other targeting motifs which are currently unrecognized.
We have studied the localization of 5-LO and 15-LO in stimulated RAW
macrophages and demonstrate that 5-LO, but not 15-LO, translocates to
the nuclear envelope in these cells. Because 5-LO and 15-LO are related
enzymes and share common structural features, we considered the
possibility that selective targeting of 5-LO is mediated by a
relatively small domain with a distinct targeting motif. 5-LO has three
putative nuclear localization signals (NLS) that are not observed in
15-LO (35-37). NLS domains target proteins to the nuclear pore for
transport into the nucleus, a distinct process from the targeting of
proteins to membrane locations. 5-LO was not imported into the nucleus
in RAW macrophages, enabling translocation to the nuclear membrane to
be studied independently of NLS-mediated transport through the nuclear
pore. We created chimeras of 5-LO and 15-LO to determine which regions
of 5-LO are essential for translocation to the nuclear envelope. Our
results provide evidence that a complex interaction of domains
throughout the molecule is required for membrane targeting and suggest
that no small linear sequence by itself can sustain nuclear envelope localization.
Plasmid Constructs--
The cDNAs coding for human 5-LO (11)
and 15-LO (12) were ligated in-frame into the EcoRI site of
EGFP-C2 (CLONTECH). Deletion mutants of 5-LO were
made by digestion of the coding region with BamHI (C Cell Culture and Transfections--
RAW 267.4 mouse macrophages
were maintained in Dulbecco's modified Eagle's medium supplemented
with 10% fetal bovine serum. The cells were grown to 50% confluency
on double chamber slides (Falcon) and transfected with 2 µg of
plasmid DNA/chamber using DEAE-dextran or SuperFect Reagent (Qiagen).
Transfection efficiencies were determined to be 5-10% by EGFP
fluorescence or by parallel transfections with
pcDNA3.1( Cell Activation and Fluorescence Analysis--
Cells were washed
three times in PBS 48 h after transfection and were then incubated
for 10 min at 37 °C in PBS containing 1 mM
Ca2+ and 5 µM A23187. The cells were fixed
for 30 min in 4% paraformaldehyde in PBS, washed twice in PBS, and
mounted under coverslips in Gel/Mount (Biomeda). EGFP fusion proteins
were localized by direct fluorescence. Representative results from
multiple transfection/cell activation experiments are shown. In control
experiments, cells were incubated for 10 min at 37 °C in PBS without
A23187 or were preincubated in PBS containing 1 µM MK-886
for 5 min at 37 °C prior to the addition of A23187. As an
alternative to A23187 stimulation, some cells were incubated with PMA
(100 ng/ml) or dibutyryl cAMP (1 mM) for 20 min at 37 °C
prior to fixation.
For indirect immunofluorescence of lamin B, nontransfected cells were
fixed as before and permeabilized with 0.1% Triton X-100 in PBS for 4 min. They were blocked in 10% goat serum for 30 min and then incubated
with rabbit anti-lamin B (Dr. J. Casanova, Massachusetts General
Hospital) diluted 1:1000 for 1 h, followed by fluoresceinated goat
anti-rabbit IgG (Molecular Probes) diluted 1:200 for 40 min.
Fluorescence was analyzed under fluorescein filters (490/525 nm) using
a Nikon FXA photomicroscope, and images were processed using IP
Spectrum acquisition analysis software (Scanalytics, Vienna, VA).
Immunoprecipitations and Western Blotting--
The expression of
the constructs was confirmed by Western blotting using a mouse
monoclonal antibody to EGFP (CLONTECH). 48 h
after transfection, the cells were extracted in 50 mM Tris
HCl, pH 7.5, 250 mM NaCl, 0.1% Nonidet P-40, 10%
glycerol, and centrifuged at 12,000 × g for 20 min.
The cell lysate was incubated with anti-EGFP diluted 1:500 for 1 h
and then with protein G-agarose (Boehringer) for 3 h. The agarose
beads were washed, and bound proteins were solubilized in SDS sample
buffer, fractionated by SDS-PAGE, and electrophoretically transferred
to nitrocellulose Trans-Blot membranes (Bio-Rad). The membranes were
incubated with anti-EGFP diluted 1:500 and sheep anti-mouse peroxidase
(Amersham Pharmacia Biotech) diluted 1:5000 and were processed for
enhanced chemiluminescence (Amersham Pharmacia Biotech). For analysis
of FLAP, RAW macrophages or HL-60 cells were suspended in 50 mM Tris HCl, pH 7.5, 5 mM EDTA, 1 mM benzamidine, 2 mM PMSF, and disrupted by
sonication at 4 °C using a Vibracell probe sonicator (3 × 1 min, setting 4, 50% output, 107 cells/ml). The sonicate
was fractionated on a 15% gel (84 µg of protein/well), transferred
to nitrocellulose, and analyzed with anti-FLAP antibody (Dr. F. Fitzpatrick, Huntsman Cancer Institute) diluted 1:200.
EGFP-15-LO and EGFP-5-LO were detected as immunoreactive bands
with the expected molecular mass of 100 and 105 kDa, respectively, following immunoprecipitation analysis of transfected RAW cells (Fig.
1). EGFP-5-LO was distributed throughout
the cytoplasm of unstimulated RAW cells (Fig.
2A). When cells were
stimulated with the calcium ionophore A23187, EGFP-5-LO translocated to
the nuclear envelope (Fig. 2D). The distribution of
fluorescence around the nucleus appeared the same as that observed
following staining for lamin B (Fig. 2C). RAW macrophages
therefore provide a convenient model system for studying nuclear
envelope translocation, and demonstrate that the machinery for
translocation (19, 20) is conserved between humans and mice.
No enrichment of fluorescence was observed on the nuclear envelope in
unstimulated RAW cells, indicating that overexpression of 5-LO is
insufficient to drive equilibrium binding to the membrane in the
absence of a calcium signal. Stimulation of cells with PMA or dibutyryl
cAMP did not induce translocation (data not shown). Western blot
analysis detected FLAP in Me2SO-induced HL-60 cells but did
not detect FLAP in uninduced HL-60 cells or RAW cells (data not shown).
In addition, translocation of 5-LO in RAW cells was not inhibited by 1 µM MK-886. These data are consistent with the model
proposed by Kargman et al. (20) in which 5-LO translocation and FLAP interaction can be two separate processes.
EGFP-15-LO was expressed in unstimulated RAW macrophages with the same
distribution as EGFP-5-LO (Fig. 2B) but did not change its
distribution with the addition of calcium ionophore (Fig. 2E). It can be concluded that 15-LO does not translocate to
membranes in RAW macrophages by the same mechanism as 5-LO. This
difference may prevent the two lipoxygenases competing for the same
pool of arachidonic acid in cells that express both enzymes. Previous studies suggest that 15-LO can associate with nonnuclear membranes in a
calcium-dependent manner (5, 29), and the resolution of our
assay system does not rule out this possibility. The results obtained
here do not necessarily extend to the movement of 15-LO in epithelial
cells but are consistent with observations in eosinophils and monocytes
(5).
We created a series of deletion mutants of 5-LO to search for domains
required for translocation to the nuclear envelope (Fig. 3). The mutants were expressed as EGFP
fusion proteins and were all localized to the cytoplasm of unstimulated
RAW cells. Deletion of the C-terminal 110 aa (C
Differential Localization of 5- and 15-Lipoxygenases to the
Nuclear Envelope in RAW Macrophages*
ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
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INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
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EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
:110
and N:564), NotI (C:79), or XhoI (C:33)
prior to ligation. EGFP-C2 does not contain a NotI cloning
site and C:79 was ligated into pcDNA3 (Invitrogen) and excised
with EcoRI and ApaI for cloning into EGFP-C2.
Chimeric 5-LO/15-LO molecules were made from the EGFP-C2 plasmid
constructs. Chimera A was made by cutting EGFP-C2/5-LO with
BglII (cuts in cloning site of EGFP-C2 upstream of 5-LO) and
XcmI (cuts at cDNA residue 749 in 5-LO) and replacing
the excised fragment with the corresponding fragment derived from
EGFP-C2/15-LO with BglII and XcmI (cuts at
residue 693 in 15-LO). Chimera B was made by cutting EGFP-C2/5-LO with BamHI (cuts in cloning site of EGFP-C2 downstream of 5-LO)
and PpuMI (cuts at residue 1369 in 5-LO) and replacing the
excised fragment. The corresponding segment of 15-LO was amplified by polymerase chain reaction using a forward primer corresponding to bp
1309-1332 with a PpuMI site added at the 5'-end
(5'-AAGGACCTAACCTACAGCTCCTTCTGTCCC-3'), and a reverse primer
corresponding to bp 1992-1969 with a BamHI site added
at the 5'-end (5'-GGATCCTTAGATGGCCACACTGTTTTCCAC-3'). Chimera C was
made by cutting EGFP-C2/15-LO with XcmI (cuts at residues
693 and 1211 in 15-LO) and replacing the excised fragment. The
corresponding segment of 5-LO was amplified by polymerase chain
reaction using a forward primer corresponding to bp 744-770 (5'-GGCTACCAGTTCCTGAATGGCTGCAAC-3'), which contains the endogenous XcmI site, and a reverse primer corresponding to bp
1286-1260 with an additional 4 bp at the 5'-end to generate an
XcmI site (5'-CCAGCTGCTCCCTGGCCTTGGTGTTGATTGC-3'). The
cycling conditions used for polymerase chain reactions were 94 °C
for 1 min, 55 °C for 1 min, and 72 °C for 1 min: 25 cycles were
followed by 1 cycle with a 10-min extension time. All constructs were
sequenced at the Massachusetts General Hospital Molecular Biology Core
Facility to confirm their identity.
)myc-His-lacZ (Invitrogen) followed by staining with
X-gal solution. HL-60 cells were maintained in RPMI supplemented with
10% fetal bovine serum and were differentiated by incubating 5 × 105 cells/ml with 1.3% Me2SO for 5 days.
RESULTS AND DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
View larger version (53K):
[in a new window]
Fig. 1.
Western blot analysis of EGFP fusion
proteins. Extracts from cells transfected with EGFP (lane
1), EGFP-15-LO (lane 2), or EGFP-5-LO (lane
3), were analyzed by immunoprecipitation and Western blotting
using a monoclonal antibody to EGFP.
View larger version (19K):
[in a new window]
Fig. 2.
Differential targeting of EGFP-5-LO and
EGFP-15-LO. RAW 264.7 macrophages were transfected with EGFP-5-LO
(A and D) or EGFP-15-LO (B and
E). The transfected cells were incubated for 10 min at
37 °C in PBS containing 1 mM Ca2+ and either
5 µM A23187 (D and E) or no A23187
(A and B). The cells were fixed, and EGFP fusion
proteins were localized by direct fluorescence. The distribution of a
chimeric 5-LO/15-LO molecule (chimera A) expressed as a
fusion protein with EGFP is shown in A23187-stimulated cells
(F). The nuclear envelope was stained by indirect
immunofluorescence of nontransfected cells using rabbit anti-lamin B
followed by fluoresceinated goat anti-rabbit IgG (C).
:110) abolished the
ability of the fusion protein to localize to the nuclear envelope. A
number of domains located in this deleted region have been suggested to play a role in translocation. A proline-rich sequence between amino
acids 565-577 resembles an SH3 binding domain and has been implicated
in mediating protein-protein interactions (34, 38). Pharmacological
evidence suggests a role for MAP kinase mediated phosphorylation as a
requisite for both nuclear envelope localization and activity (38, 39),
presumably by phosphorylation of a MAP kinase/Cdc2 kinase site at aa
662-667. The ability of these domains to support translocation by
themselves was tested using the N:564 mutant in which the C-terminal
110 aa were expressed as an EGFP fusion protein. The protein could not
translocate to the nuclear envelope, indicating that although this
C-terminal region is required for translocation it is not by itself
sufficient.
View larger version (27K):
[in a new window]
Fig. 3.
Nuclear envelope targeting of C-terminal
deletion mutants of EGFP-5-LO. Deletion mutants of 5-LO were
cloned into the EGFP-C2 vector (CLONTECH) and
expressed in RAW macrophages. Targeting result indicates whether EGFP
fusion proteins were localized to the nuclear envelope (++) or remained
diffuse in the cytoplasm ( ) following A23187 stimulation. The
locations of moderately hydrophobic domains (hatched boxes)
and proline-rich domains (black boxes) in the 5-LO protein
are indicated. The exact sequence containing consensus sites for MAP
kinase (YLSP, aa 662-665) and Cdc2 kinase (SPDR, aa 664-667) in the
C-terminal is shown. The basic motif RNKKK (aa 652-656) forms a
putative bipartite nuclear localization signal (NLS) with
other basic amino acids further downstream (36) or upstream (37).
Smaller deletions of the C-terminal (the C:79 truncation which
includes the proline-rich domain but not the MAP kinase site, and the
C:33 truncation which lacks the kinase site but contains an extended
portion of the C-terminal) do not localize to the nuclear envelope on
cell stimulation. However, these deletion mutants had a low level of
expression, and we cannot rule out the possibility that the deletions
affect folding and disrupt the molecule over a more extensive region.
Deletion of the C-terminal isoleucine is sufficient to prevent
co-ordination with iron and probably results in improper folding which
blocks enzyme activity (14). To circumvent this problem, we created a
series of chimeras between 5-LO and 15-LO (Fig.
4). These were chosen to allow the chimeric molecule to retain common LO structural properties in an
intact configuration while replacing domains of 5-LO with those of the
homologous nontargeted 15-LO molecule. For example, 15-LO contains a
C-terminal isoleucine that can participate in binding iron so as to
maintain structural integrity. It was not considered essential to
retain enzyme activity in the chimeras because targeting domains are
often modular and generally less sensitive to small variations in
folding. The chimeras, that were expressed as EGFP fusion proteins, all
localized to the cytoplasm of resting RAW cells.
|
When aa 1-237 at the N-terminal of 5-LO were replaced with the corresponding aa 1-232 of 15-LO, the resulting molecule (chimera A) retained the ability to translocate after addition of A23187 (Fig. 2F). The fluorescence observed on the nuclear envelope, however, was of lower intensity than that seen with the native 5-LO fusion protein. This might indicate a reduced efficiency of translocation, but nuclear envelope localization was clearly discernible and distinct from unstimulated cells. In contrast, replacement of the C-terminal 231 aa of 5-LO with the corresponding aa of 15-LO (chimera B) abolished translocation. This chimeric molecule lacks the C-terminal MAP kinase site but contains a proline-rich region the same distance from the C-terminal as in native 5-LO. The C-terminal proline-rich regions of 5-LO and 15-LO are closely related (10 aa are identical in the 13 aa sequence). Both contain two prolines in critical positions for binding the polyproline helix to an SH3 domain. Exchange of the proline-rich domains is therefore unlikely to account for the loss of targeting of chimera B. This domain might mediate interactions with cytoskeletal proteins in the cytoplasm (34, 38) rather than with the nuclear envelope.
15-LO contains a second proline-rich region between aa 326-338. This also resembles an SH3 binding domain but has a different context and might mediate different interactions. It is centrally located in a region which contains the most hydrophobic portions of the molecule. Hydropathy plots derived by the method of Kyte and Doolittle (40) are very similar for both 15-LO and 5-LO, and the moderately hydrophobic domains shown in Figs. 3 and 4 (hatched boxes) correspond to aa 278-326 and 352-424 in 5-LO (41). The latter segment contains hydrophobic amino acids that form a binding pocket for arachidonic acid and two histidines that coordinate iron at the active site. 5-LO and 15-LO appear structurally similar throughout this region, but 5-LO does not contain a central proline-rich domain. We considered the possibility that this domain might be sufficient to prevent translocation of 15-LO to the nuclear envelope by mediating inhibitory interactions or alternative targeting. We replaced the central core of 15-LO (aa 233-403) with the corresponding region (aa 238-411) of 5-LO. The resulting molecule (chimera C) localized to the cytoplasm but remained unable to translocate to the nuclear envelope after cell stimulation with A23187, ruling out this possibility.
The lack of targeting of chimera C and the C:110 deletion mutant
indicate that the hydrophobic regions in the core of 5-LO are
insufficient for membrane association. These mutant molecules remained
exclusively in the cytoplasm and did not show any detectable localization to membrane boundaries. The C-terminal portion of the
molecule is also insufficient for targeting (deletion mutant N:564)
but the results using chimera B confirm its importance. The critical
part of the C-terminal cannot be localized to the proline-rich domain
because this is substituted with a homologous domain in chimera B. Collectively our results demonstrate that no small linear domain by
itself can sustain nuclear envelope localization of 5-LO, and targeting
must depend on cooperative interactions between different parts of the
molecule. The N-terminal 237 aa of 5-LO do not appear to be essential
for membrane interaction but may still participate. Chimera A was able
to translocate to the nuclear envelope on cell stimulation but with
reduced efficiency. The N-terminal of 15-LO contains a lipase-like
-barrel of 115 amino acids (16) which might serve a permissive role
in mediating membrane localization of chimera A. The N-terminal
portions of 5-LO and 15-LO (aa 1-237) share 56% amino acid identity
and might exhibit similar secondary structures.
Recent studies describe localization of 5-LO in the nucleus of certain cells (42-46). Import of proteins into the nucleus is mediated by NLS sequences, and the 5-LO molecule has three putative NLS domains that may contribute to this transport step (35). However, transport of 5-LO through the nuclear pore probably represents a distinct event from targeting to the membranes of the nuclear envelope. For example, a nuclear pool of 5-LO is associated with alveolar macrophages and recruited neutrophils, but this is distributed throughout the nucleoplasm and still requires a calcium stimulus to translocate to the nuclear membrane (45, 46). In the present study no fluorescence was detected in the nucleoplasm of RAW macrophages in resting cells or at any observation time up to 20 min after the addition of A23187. This suggests that translocation occurs from the cytoplasm to the outer nuclear membrane and is independent of the NLS domains in the 5-LO molecule in these cells.
15-LO lacks putative NLS domains, but this may not be a sufficient explanation for its failure to target to the outer nuclear membrane in RAW macrophages which do not appear to import 5-LO into the nucleus. The role of NLS domains in 5-LO has been investigated with EGFP fusion proteins (36). This work is distinct from our study because it analyzes movement from the cytoplasm to the nucleoplasm rather than translocation to the nuclear envelope. Taken together the two studies suggest considerable complexity in both nuclear transport and nuclear envelope localization. It has recently been suggested that there may in fact be mechanistic links between the two events (37), for example docking of 5-LO at the nuclear pore might be an intermediate step which enables 5-LO to engage other binding partners in the plane of the membrane. A putative NLS at aa 652-656 was implicated in participating in nuclear envelope localization (37). Our observations do not rule out this possibility because NLS[652-656] is located within the critical C-terminal domain required for translocation of 5-LO in RAW macrophages.
Unlike cPLA2 and conventional isoforms of protein kinase C,
5-LO does not contain an obvious calcium-binding domain. 5-LO co-localizes with cPLA2 and FLAP in the nuclear envelope,
but no direct interactions with these proteins have yet been
demonstrated. Despite recent analyses of putative nuclear localization
signals (36, 37), 5-LO still has no clearly identifiable targeting motif to direct translocation to the nuclear envelope. Our comparison of 5-LO with a homologous nontargeted enzyme (15-LO) in RAW macrophages suggest that multiple domains participate in mediating translocation to
the nuclear envelope and demonstrate that the two enzymes use separate
mechanisms to access a common substrate.
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ACKNOWLEDGEMENT |
|---|
We thank Dr. Sylvie Breton for assistance with microscopy studies.
| |
FOOTNOTES |
|---|
* This work was supported by National Institutes of Health Grants R01ES-50859 (to R. J. S.), PO1DK-38452, and P30DK-43351, and a gift from the Jewish Communal Fund (to R. J. S.).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.
To whom correspondence should be addressed: Arthritis Unit,
Massachusetts General Hospital East, 149 The Navy yard, 13th St., Charlestown, MA 02129. Tel.: 617-726-3747; Fax: 617-726-5651; E-mail: Soberman@helix.mgh.harvard.edu.
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ABBREVIATIONS |
|---|
The abbreviations used are:
LO, lipoxygenase;
EGFP, enhanced green fluorescent protein;
cPLA2, cytosolic
phospholipase A2;
FLAP, 5 lipoxygenase-activating protein;
SH3, c-Src homology 3 domain;
PMA, phorbol 12-myristate 13-acetate;
bp, base pair(s);
aa, amino acid(s);
DEAE, diethylaminoethyl;
PBS, phosphate-buffered saline;
PMSF, phenylmethylsulfony fluoride;
NLS, nuclear localization signal;
X-gal, 5-bromo-4-chloro-3-indolyl
-D-galactopyranoside;
MAP, mitogen-activated
protein.
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REFERENCES |
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ABSTRACT
INTRODUCTION
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RESULTS AND DISCUSSION
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