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From the
Received for publication, May 6, 2002, and in revised form, June 17, 2002
Intracellular neutral lipid storage droplets are
essential organelles of eukaryotic cells, yet little is known about the
proteins at their surfaces or about the amino acid sequences that
target proteins to these storage droplets. The mammalian
proteins Perilipin, ADRP, and TIP47 share extensive amino acid sequence
similarity, suggesting a common function. However, while Perilipin and
ADRP localize exclusively to neutral lipid storage droplets, an
association of TIP47 with intracellular lipid droplets has been
controversial. We now show that GFP-tagged TIP47 co-localizes with
isolated intracellular lipid droplets. We have also detected a close
juxtaposition of TIP47 with the surfaces of lipid storage droplets
using antibodies that specifically recognize TIP47, further indicating
that TIP47 associates with intracellular lipid storage droplets.
Finally, we show that related proteins from species as diverse as
Drosophila and Dictyostelium can also target
mammalian or Drosophila lipid droplet surfaces in
vivo. Thus, sequence and/or structural elements within
this evolutionarily ancient protein family are necessary and sufficient
to direct association to heterologous intracellular lipid droplet
surfaces, strongly indicating that they have a common function for
lipid deposition and/or mobilization.
The intracellular neutral lipid storage droplets
(LSDs)1 of eukaryotes are
ubiquitous cellular organelles required for membrane biosynthesis,
cholesterol metabolism, lipid trafficking, and energy balance. In the
Metazoa, the ADRP and Perilipin (Peri) proteins associate
exclusively with the surface of these lipid droplets (1-5). ADRP
mRNA is expressed ubiquitously, whereas Peri expression is limited
to adipocytes and steroidogenic cells (2, 4, 6). However, the
expressions of ADRP and Peri protein are mutually exclusive; ADRP
protein is not detected in cells that also express Peri. The common
targeting properties of ADRP and Peri to LSDs, nonetheless, suggest a
functional linkage for lipid deposition and mobilization (7-9).
Peri is required for lipid storage in adipose tissue.
peri Peri and ADRP share extensive sequence similarity (6, 15, 16). The
initial ~120 amino acids of ADRP and Peri are ~40% identical (6)
and a more limited but statistically significant similarity is observed
within the ~150 adjacent amino acids (15). The mannose
6-phosphate/IGF-II receptor (MPR/IGF-IIR) trafficking protein TIP47 has
a sequence organization that is also similar to Peri and ADRP (15, 17).
Overall, ADRP and TIP47 are ~50% identical in amino acid sequence.
Computational analyses (15) also identified proteins in species as
diverse as Drosophila (LSD-1 and -2) and
Dictyostelium (LSD1) that are related to Peri, ADRP, and
TIP47. Collectively, we termed these PAT proteins, where
Peri, ADRP, and TIP47 define the
core of the family (15). Further, two PAT subdomains were described;
PAT-1 defines the high identity N-terminal region, and PAT-2 defines
the more distal region of lesser similarity (15). The conserved
splice site junctions between murine ADRP and
Drosophila LSD-1 genes emphasize the evolutionary relationships among diverse gene family members (15).
TIP47 was originally identified by its ability to interact with the
MPR/IGF-IIR. However, the sequence similarities between TIP47 and ADRP
(15, 17) prompted a re-examination of the subcellular localization of
TIP47 (18). Indeed, LSD association was detected using antibodies to
TIP47 (18), but unfortunately the data were inconclusive. The Here we have examined the subcellular localizations of PAT family
proteins TIP47, LSD1 from Dictyostelium, and LSD-1 and -2 from Drosophila. Using two new reagents, GFP-tagged TIP47
and a TIP47-specific antibody, we have confirmed the ability of TIP47 to co-localize with lipid storage droplets. Finally, we have
demonstrated that LSD1 of Dictyostelium and LSD-1 and -2 of
Drosophila also co-localize in vivo with lipid
storage droplets in mammalian tissue culture cells and, for LSD-1 and
-2, in cells of Drosophila fat bodies.
GFP Fusion Constructs--
Full-length cDNA
constructs were fused in-frame with the 3' end of eGFP in
pEGFP-C2 (CLONTECH) or pUAST (20). The coding sequences of murine PeriA and murine ADRP
(NM007408) were obtained from previously existing clones (15, 16).
Murine TIP47 (AI892835) cDNA was obtained from the IMAGE
consortium (ID no. 571955). Dictyostelium LSD1 (AU061427)
cDNA (SLE217) was obtained from the Dictyostelium cDNA project (21). Drosophila LSD-1 (AF357214) and
LSD-2 (AY060242) cDNA were isolated by RT-PCR using MMLV
reverse transcriptase (CLONTECH) and Deep Vent
polymerase (New England Biolabs) from adult
Drosophila head RNA. Expression of full-length eGFP,
GFP-Peri, GFP-ADRP, GFP-TIP47, GFP-LSD-1, GFP-LSD-2, and GFP-LSD1
proteins in Chinese hamster ovary (CHO) cells was confirmed by Western
blotting using Cell Culture--
CHO fibroblasts were cultured in Ham's F-12
medium supplemented with 10% fetal bovine serum, 2 mM
glutamine, 100 units/ml penicillin, and 100 µg/ml streptomycin. Human
HeLa cells were cultured in Dulbecco's modified Eagle's medium
supplemented with 20% fetal bovine serum, 2 mM glutamine,
100 units/ml penicillin, and 100 µg/ml streptomycin at 3 × 105 cells per well in 50-mm diameter culture dishes
attached with a coverslip. All cells were cultured in 5%
CO2 atmosphere at 37 °C. Intracellular neutral lipid
storage was increased by the addition of oleic acid coupled to bovine
serum albumin (1).
Transformation and Transgenesis--
CHO fibroblasts were
transfected with 2 µg of DNA using LipofectAMINE Plus (Invitrogen).
Cells were then cultured overnight at 5 × 105 cells
per well in a 50-mm diameter culture dish attached with a coverslip.
Transgenic Drosophila were produced by P-element-mediated transformation using the bipartite GAL4/UAS
system (22, 23). Expression of UAS::transgenes was
directed by hs::GAL4 following 1 h
of heat shock at 37 °C and a 3-h recovery at 25 °C.
Microscopy--
CHO and HeLa cells and Drosophila
embryos were treated with 400 nM Nile Red (Molecular
Probes, Inc.) for 5 min. Neutral lipid droplets were visualized by
confocal laser microscopy (LSM 510, Zeiss). HeLa cells were fixed with
3% paraformaldehyde in phosphate-buffered saline for 60 min and
blocked prior to immunostaining. Primary rabbit anti-human TIP47 and
fluorescein isothiocyanate-conjugated goat anti-rabbit (Jackson
ImmunoResearch) were added sequentially to the fixed cells in
phosphate-buffered saline containing 0.1% saponin and 28.5 mg/ml
Chrompure goat IgG (Jackson ImmunoResearch). The samples were stained
with 8 pM Nile red in buffer containing 0.1% saponin and
1× phosphate-buffered saline for 1 min. Images were obtained by
confocal laser microscopy using a ×63 water objective lens.
Fractionation of CHO cells--
CHO cells were grown,
transfected, lipid loaded, and lysed in 10 mM Tris-HCl, pH
7.4, 1 mM EDTA, 10 µg/ml leupeptin, 100 µM AEBSF, and 1 mM benzamidine by five passages through a
25-gauge needle. The homogenate was centrifuged at 1000 × g at 4 °C. for 10 min. The supernatant was adjusted to
18.46% sucrose and centrifuged at 165,000 × g for
1 h at 4 °C. The buoyant fraction was adjusted to 1.5 ml with
lysis buffer. 1 µl of sample was mixed with 1 µl of 80 pM Nile Red in 1× phosphate-buffered saline and mounted to
a glass slide with 4 µl of 80% glycerol in 1× phosphate-buffered saline. The prepared slide was viewed by confocal laser microscopy using a ×63 water objective lens.
Comparative Sequence Analyses--
PAT proteins were identified
previously in an NCBI search (15). Their PAT domain sequences (see Ref.
15) were aligned using ClustalW with the PAM350 matrix provided in the
MacVector 7.1 program package. A schematic, unrooted tree was predicted by neighbor-joining methodology. Numbers at the branch nodes represent bootstrap values (as percentages) obtained in 1000 replications. s3-12
is an adipocyte protein with a repeating 33-mer element that shares
similarity with the PAT family (24). For the alignment, s3-12 was
manually deleted of all but two 33-mer repeats (see Ref. 15). Human
caveolin 1 and human Sequence Relationships among the PAT Protein Family--
We had
previously identified (15) PAT family proteins in representative
species as diverse as vertebrates, Drosophila, and Dictyostelium that are related to Peri and ADRP. Sequence
analyses based upon neighbor-joining comparisons now confirm separate
vertebrate groupings for Peri, ADRP, and TIP47. A novel murine family
member, PAT1, was also identified. Although the Drosophila
and Dictyostelium proteins are more distantly related, they
demonstrate clear PAT group association (Fig.
1).
TIP47 Co-localizes with Lipid Storage Droplets--
The
subcellular localization of TIP47 has been controversial (18, 19).
TIP47 was originally identified in a screen for proteins that interact
with the MPR/IGF-IIR (17). Subsequently, antibodies to TIP47 were shown
to detect protein at lipid droplet surfaces (18), but because these
antibodies cross-reacted with ADRP, it was not possible to assert
unequivocally that TIP47 exhibits lipid droplet co-localization (19).
We have used two approaches to resolve this controversy. First, to
circumvent potential issues of antibody cross-reactivity we visualized
TIP47 localization in fusion with GFP. Second, we also generated
antibodies to human TIP47 that were directed against peptide sequences
that are absent from human ADRP (i.e. adipophilin).
CHO cells expressing GFP-TIP47 were grown with oleic acid to increase
intracellular neutral lipid stores. Cells expressing GFP-Peri and
GFP-ADRP served as positive controls, and cells expressing unfused eGFP
served as a negative control. The cells were stained with Nile Red to
visualize the clustered neutral lipid droplets (Fig.
2). Images are centered upon clusters of
the intracellular neutral lipid droplets and surrounding areas of
cytosol. eGFP showed broad and diffuse fluorescence throughout the
cytoplasm with clear exclusion from the lipid droplets (Fig. 2).
Conversely, GFP-Peri and GFP-ADRP localized exclusively with the
surfaces of lipid storage droplets. No overt fluorescence was detected in other compartments (Fig. 2). Confocal cross-sections of lipid droplet clusters showed characteristic rings of Peri and ADRP localization in contact with these neutral lipid stores (Fig. 2).
GFP-TIP47 fluorescence was more complex than for eGFP, GFP-Peri, or
GFP-ADRP (Fig. 2). TIP47 appears to be distributed throughout the
cytoplasm. However, unlike that observed for eGFP, GFP-TIP47 fluorescence also appears to be associated with the lipid droplets. Indeed, definitive rings of GFP-TIP47 fluorescence are discerned above
the general cytoplasmic background. The merged Nile Red and GFP images
reveal the distinct accumulation of TIP47 around the lipid droplets
with the apparent ring structures that are typical in cross-sectional
views of protein localization at the surface of lipid droplets. This
fluorescence pattern is not the result of simple exclusion from the
lipid droplet, because no ring structures were observed in similar
views of cells expressing only eGFP (Fig. 2). To further confirm the
lipid droplet association of GFP-TIP47, we isolated neutral lipid
droplets from these CHO cells and followed the fluorescence of eGFP,
GFP-Peri, and GFP-TIP47 (Fig. 3). Images
of isolated droplets from GFP-Peri- and GFP-TIP47-expressing cells were
effectively indistinguishable, clearly demonstrating the close
association of TIP47 at the droplet surface. eGFP did not co-isolate
with the lipid droplets. These data indicate that GFP-TIP47 can
associate closely with the lipid droplet surface, but they do not
exclude an ability of TIP47 to interact with other subcellular
components or structures (see Refs. 17, 19, 25).
To exclude the possibility that GFP-TIP47 localization may not
accurately reflect the targeting of native protein (see Ref. 25), we
examined the intracellular association of endogenous TIP47 by
immunofluorescence with antibodies selective for human TIP47. TIP47 and
ADRP are closely related in sequence. Accordingly, we selected peptides
of human TIP47 that are not related to sequences in human ADRP for
antigen production and for affinity purification. Affinity-purified
antibodies to human TIP47 only recognized a single protein, of ~45
kDa, in HeLa cells (Fig. 4A).
However, TIP47 and ADRP proteins are both ~45 kDa. We, therefore,
expressed human TIP47 and human ADRP to high levels in CHO cells and
probed for cross-reactivity of TIP47 antibody with ADRP. As seen in
Fig. 4B, the affinity-purified antibody to human TIP47 only
recognized protein in the TIP47-expressing CHO cells and not in the CHO
cells that express high levels of human ADRP. Thus, the
affinity-purified antibody has strong specificity for human TIP47.
We then used the affinity-purified antibody to human TIP47 to examine
subcellular localization of endogenous TIP47 in HeLa cells. The small
lipid droplets characteristic of HeLa cells were clearly evident by
Nile Red fluorescence, and TIP47 was found predominantly in very close
juxtaposition (Fig. 5). We did not observe the strong, diffuse cytoplasmic distribution of TIP47 that was
apparent when full-length TIP47 was highly expressed as a GFP fusion in
CHO cells. Nonetheless, the GFP-TIP47 fusion experiments in conjunction
with other reports (17, 19, 25) raise the possibility that TIP47 may be
multifunctional, potentially trafficking proteins and/or lipids among
several compartments. Perhaps different environmental parameters alter
the relative distribution of TIP47 among various intracellular
compartments. TIP47 would not be unique in its ability to associate
with LSD and non-LSDs, depending upon the physiological state of the
cell (26-33).
Drosophila and Dictyostelium PAT Proteins Also Co-localize with
LSDs--
To determine whether lipid droplet localization is a general
quality of the more diverged PAT protein members, we examined the
intracellular targeting of Drosophila LSD-1 and -2 and of Dictyostelium LSD1 in CHO cells as fusions with GFP. All of
the proteins showed selective localization of fluorescence to the lipid
droplet surface that was exclusive of any other compartment (Fig.
6). Fluorescent GFP rings were in close
apposition with the neutral lipids. These data indicate that lipid
droplet targeting is characteristic of PAT family proteins and that
sites for their recruitment are highly conserved despite their
effective separation through nearly one billion years of evolution.
We also examined the localization of Drosophila LSD-1 and -2 proteins in their endogenous environment. Transgenic
Drosophila were generated that expressed
GFP-LSD-1 or -2 genes driven with a
GAL4-inducible promoter. The GAL4 transcriptional regulatory protein was induced by heat shock response. The GFP-LSD-1 (Fig. 7) and -2 proteins (not shown) were
clearly shown to associate with lipid droplets within cells of larval
(first instar) fat bodies, as evidenced by the rings of GFP
fluorescence surrounding the large lipid droplets in these cells. These
data confirm that LSD-1 and -2 proteins can associate specifically with
lipid droplets in a native environment, as well as in mammalian CHO
cells.
In summary, the PAT protein family has ancient progenitors that define
a novel protein targeting component for association with intracellular
lipid storage droplets. A common sequence and/or structural element
among these proteins is necessary and sufficient for this functional
conservation even within exogenous cellular environments. Further,
structure/function studies of Peri demonstrate its essential role in
lipid storage droplet deposition and mobilization (9-13), strongly
suggesting related roles for ADRP, TIP47, and other PAT proteins in
lipid metabolism and trafficking (7, 8, 14). The PAT family has no
apparent sequence relationship with the variety of other proteins
capable of lipid droplet association in plants, yeasts, or mammalian
cells, including the oleosins, caveolin, and synuclein (25-32).
Nonetheless, the confirmation that the distantly related PAT proteins
of Drosophila and Dictyostelium also possess the
essential structural elements for LSD targeting emphasizes this
functional characteristic. Directed and complementary studies using
both mammalian and non-mammalian systems will be required to dissect
the molecular mechanisms that are a fundamental property of this
important protein family.
We greatly appreciate the efforts of the
Dictyostelium cDNA project in Japan and the Berkeley
Drosophila Genome Project and gratefully acknowledge access
to unpublished communications from Drs. Dawn Brasaemle and Nat Wolins.
We are indebted to members of the Londos and Kimmel labs for continuous
support and discussions, with particular acknowledgment to Drs. John
Tansey and Carole Sztalryd. The advice and expertise of Heidi Dorward
on confocal microscopy was invaluable as was that of Virginia Boulais
for establishing and maintaining Drosophila lines.
*
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.
§
Supported by the Japan Society for the Promotion of Science.
Present Address: Div. of Clinical Nutrition, Dept. of Human Nutrition, National Institutes of Health and Nutrition, 1-23-1 Toyama,
Shinjuku-ku, Tokyo, 162-8636, Japan.
**
Present Address: Howard Hughes Medical Institute, 4000 Jones Bridge
Rd., Chevy Chase, MD 20815-6789.
Published, JBC Papers in Press, June 20, 2002, DOI 10.1074/jbc.M204410200
The abbreviations used are:
LSD, liquid
storage droplet;
Peri, Perilipin;
PAT, Peri, ADRP, and TIP47 proteins;
GFP, green fluorescence protein;
eGFP, enhanced GFP;
CHO, Chinese
hamster ovary;
IGF, insulin-like growth factor;
MPR/IGF-IIR, mannose
6-phosphate/IGF-II receptor.
Functional Conservation for Lipid Storage Droplet Association
among Perilipin, ADRP, and TIP47 (PAT)-related Proteins in Mammals,
Drosophila, and Dictyostelium*
§,,
,**,
,, and Membrane Regulation Section, the
Developmental Biochemistry Section, and the ¶ Molecular
Mechanisms of Development Section, Laboratory of Cellular and
Developmental Biology, NIDDK, National Institutes of Health,
Bethesda, Maryland 20992-8028
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
/ mice have very reduced adipose tissue
mass, and isolated adipocytes from these animals exhibit greatly
elevated basal lipolytic activity when compared with wild-type (9, 10).
Similarly, Peri confers lipolytic protection to LSDs of unstimulated
adipocytes (9, 10) and of various cultured cells that express Peri
ectopically (11-13). In addition to this protective function, Peri is
required to achieve maximal lipolytic activity in stimulated cells (9, 10), suggesting that Peri is also required to facilitate lipolysis. These antagonistic regulatory functions demonstrate that Peri plays a
major role in lipid storage and mobilization. Although the ADRP is less
well studied, biochemical studies indicate a role for ADRP in lipid
trafficking from lung lipofibroblasts to type 2 epithelial cells for
surfactant biosynthesis (14).
-TIP47
antibody used also demonstrated cross-reactivity with the related ADRP,
a bona fide lipid storage droplet protein (19).
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
-GFP. Full-length human TIP47 (O60664) and human ADRP
(adipophilin, Q99541) proteins were also expressed in CHO cells.
(Accession numbers are from GenBankTM.)
-TIP47 Antibodies--
Two unique sequences, MSADGAEADGSTQ
and NQKQLQGPEKEPPK, of human TIP47 were selected to generate peptides
for antibody production. These are highly divergent regions that have
no sequence similarity to ADRP or other proteins in the non-redundant
data base of GenBankTM. The corresponding sequences from
human ADRP are MASVAVDPQPSVV and KRSIGYDDTDESHC. The peptides were
cross-linked to KLH and used collectively as antigens in rabbits. The
antibodies were affinity-purified to peptide NQKQLQGPEKEPPK of human
TIP47. Western blotting confirmed specificity for human TIP47 (see Fig.
4).
-actin were included in the unrooted tree.
RESULTS AND DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
View larger version (18K):
[in a new window]
Fig. 1.
Sequence relationships among PAT family
proteins. PAT proteins were identified in an NCBI search (15). A
schematic tree was predicted by neighbor-joining using amino acid
sequences of the PAT subdomains (15). Numbers at the branch nodes
represent bootstrap values (as percentages) obtained in 1000 replications. For the alignment, s3-12* (24) was manually deleted of
all but two of its 33-mer repeats (see Ref. 15). Human caveolin 1, an
unrelated protein that displays lipid association, and human -actin
were included in the unrooted analyses. Proteins used in this study are
in boldface.
View larger version (70K):
[in a new window]
Fig. 2.
GFP-tagged murine Peri, ADRP, and TIP47
target to lipid storage droplets in CHO cells. CHO cells were
transfected with the pEGFP-C2 vector or with the vector containing
coding sequences of murine Peri, ADRP, and TIP47. The cells were grown
in the presence of oleic acid, and neutral lipids were stained with
Nile Red. Fluorescent and phase images of subcellular lipid
clusters were generated by confocal laser microscopy.
View larger version (46K):
[in a new window]
Fig. 3.
GFP-tagged murine Peri and TIP47 associate
with isolated lipid storage droplets. CHO cells were transfected
with the pEGFP-C2 vector or with the vector containing coding sequences
of murine Peri and TIP47. The cells were grown in the presence of oleic
acid, and the intracellular lipid droplets were purified and stained
with Nile Red. Fluorescent and phase images were generated by confocal
laser microscopy.
View larger version (35K):
[in a new window]
Fig. 4.
-human TIP47 antibodies do not
cross-react with human ADRP. A, whole-cell proteins were
prepared from HeLa cells, separated by SDS-gel electrophoresis, blotted
to filters, and probed with affinity-purified antibody to human TIP47.
B, whole-cell proteins were prepared from CHO cells that
express specifically human TIP47 or human ADRP and separated by SDS-gel
electrophoresis. Identical protein blots were probed with
affinity-purified antibody to human TIP47 or antibody to human
ADRP.
View larger version (54K):
[in a new window]
Fig. 5.
Co-localization of human TIP47 with lipid
storage droplets of HeLa cells. HeLa cells were grown in the
presence of oleic acid. HeLa cells were stained for neutral lipids with
Nile Red and for endogenous TIP47 with affinity-purified antibody to
human TIP47 (see Fig. 4). Fluorescent images were obtained by confocal
laser microscopy.
View larger version (54K):
[in a new window]
Fig. 6.
Drosophila and
Dictyostelium GFP-tagged LSDs target to lipid storage
droplets in CHO cells. CHO cells were transfected with pEGFP-C2
vector containing coding sequences from Drosophila LSD-1 and
-2 and Dictyostelium LSD1. The cells were grown
in the presence of oleic acid and stained with Nile Red. Fluorescent
and phase images were generated by confocal laser microscopy.
View larger version (75K):
[in a new window]
Fig. 7.
GFP-tagged LSD-1 localizes to lipid storage
droplets of Drosophila adipocytes of first instar
larvae. Fluorescent and phase images of heat-shocked
hs::Gal4/+;UAS::Lsd-1::gfp/+
first instar larvae fat body were generated by confocal laser
microscopy.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed: 50 South Dr.
(50/3140). Tel.: 301-496-6991; Fax: 301-496-5239; E-mail:
clondos@ helix.nih.gov.
ABBREVIATIONS
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ABSTRACT
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EXPERIMENTAL PROCEDURES
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