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J. Biol. Chem., Vol. 282, Issue 2, 996-1002, January 12, 2007

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Control of Adipose Triglyceride Lipase Action by Serine 517 of Perilipin A Globally Regulates Protein Kinase A-stimulated Lipolysis in Adipocytes^*

Hideaki Miyoshi, James W. Perfield, II, Sandra C. Souza, Wen-Jun Shen^¶, Hui-Hong Zhang, Zlatina S. Stancheva, Fredric B. Kraemer^¶, Martin S. Obin¹, and Andrew S. Greenberg²

From the Jean Mayer United States Department of Agriculture Human Nutrition Research Center on Aging, Tufts University, Boston, Massachusetts 02111, Hokkaido University Graduate School of Medicine, Sapporo 060-8638, Japan, and ^¶Veterans Affairs Palo Alto Health Care System and Stanford University, Palo Alto, California 94305

Received for publication, June 15, 2006 , and in revised form, November 15, 2006.

	ABSTRACT

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Phosphorylation of the lipid droplet-associated protein perilipin A (Peri A) mediates the actions of cyclic AMP-dependent protein kinase A (PKA) to stimulate triglyceride hydrolysis (lipolysis) in adipocytes. Studies addressing how Peri A PKA sites regulate adipocyte lipolysis have relied on non-adipocyte cell models, which express neither adipose triglyceride lipase (ATGL), the rate-limiting enzyme for triglyceride catabolism in mice, nor the "downstream" lipase, hormone-sensitive lipase (HSL). ATGL and HSL are robustly expressed by adipocytes that we generated from murine embryonic fibroblasts of perilipin knock-out mice. Adenoviral expression of Peri A PKA site mutants in these cells reveals that mutation of serine 517 alone is sufficient to abrogate 95% of PKA (forskolin)-stimulated fatty acid (FA) and glycerol release. Moreover, a "phosphomimetic" (aspartic acid) substitution at serine 517 enhances PKA-stimulated FA release over levels obtained with wild type Peri A. Studies with ATGL-and HSL-directed small hairpin RNAs demonstrate that 1) ATGL activity is required for all PKA-stimulated FA and glycerol release in murine embryonic fibroblast adipocytes and 2) all PKA-stimulated FA release in the absence of HSL activity requires serine 517 phosphorylation. These results provide the first demonstration that Peri A regulates ATGL-dependent lipolysis and identify serine 517 as the Peri A PKA site essential for this regulation. The contributions of other PKA sites to PKA-stimulated lipolysis are manifested only in the presence of phosphorylated or phosphomimetic serine 517. Thus, serine 517 is a novel "master regulator" of PKA-stimulated adipocyte lipolysis.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Triglyceride (TAG)³ and other neutral lipids are stored in adipocyte lipid droplets (LDs) and, in response to energy demand, are hydrolyzed by lipases (lipolysis) to generate fatty acids (FAs) as fuel for peripheral tissues (1–5). Tight regulation of adipocyte lipolysis in response to the inhibitory actions of insulin and the stimulatory actions of lipolytic hormones such as catecholamines maintains whole body energy homeostasis and metabolic health (6–8). Catecholamines bind to -adrenergic receptors on adipocytes, resulting in up-regulation of adenyl cyclase, activation of cAMP-dependent protein kinase A (PKA), and increased lipolytic rate (9). The ability of PKA to stimulate adipocyte lipolysis is mediated in large part by the LD-associated phosphoprotein perilipin (Peri) (1, 10, 11). Peri A (the predominant perilipin isoform in adipocytes) is the most prevalent PKA substrate in adipocytes. In the absence of hormonal stimulation (i.e. basal state), Peri A functions to sequester lipases from stored neutral lipid, thereby maintaining a low rate of constitutive lipolysis. After phosphorylation by PKA, Peri A facilitates lipase accessibility to lipid stores, thereby promoting lipolysis (12–20). The mechanism(s) by which Peri A phosphorylation facilitates TAG/lipase interaction in adipocytes is not elucidated.

Previous studies of Peri A function have focused on the ability of Peri A to regulate the lipolytic actions of HSL (15–18). HSL was considered to be the rate-limiting lipase for TAG hydrolysis (21–23) until the recent discovery and characterization of ATGL (24–28). Our current view is that the two lipases work hierachically to hydrolyze TAG to FAs and glycerol. ATGL is the "initiator" lipase, with TAG-selective acylhydrolase activity and limited activity toward DAG. The DAG generated by ATGL action on TAG is then hydrolyzed to (additional) FAs and glycerol by HSL, which is suggested to be more effective as a DAG hydrolase than as a TAG hydrolase (24, 26–29). The recent demonstration that ATGL is rate-limiting for hormone-stimulated TAG catabolism in adipocytes (28) suggested that the mechanism by which Peri A regulates hormone-stimulated lipolysis must be directed at least in part toward regulating ATGL function. To our knowledge, no study has examined Peri A-dependent regulation of ATGL lipolytic action.

Peri A contains six consensus PKA sites (serine residues) (30) (see Fig. 1A). The identification of a Peri A PKA site(s) that regulates PKA-stimulated adipocyte lipolysis and the mechanism(s) by which this regulation is achieved has been addressed almost exclusively with non-adipocyte model systems, which lack adipocyte lipases (ATGL and HSL) (15–19). Notwithstanding these limitations, ectopic expression of Peri A PKA site mutants and HSL in these models suggests that PKA-stimulated lipolysis mediated by (ectopic) HSL requires phosphorylation of one or more Peri A N-terminal PKA sites (sites 1, 2, and 3 = serines 81, 223, and 277) (see Fig. 1A) (15–17); in contrast, PKA-stimulated lipolysis mediated by an (as yet unidentified) endogenous lipase(s) other than HSL requires phosphorylation of one or more Peri A C-terminal PKA sites (sites 4, 5, and 6 = serines 433, 492, and 517) (see Fig. 1A) (16). PKA site 5 was recently identified in fibroblasts as a regulator of PKA-induced LD dispersion, an event that is required for chronic (greater than 5 h) PKA-stimulated TAG breakdown (19). No function of any other individual Peri A PKA site has been demonstrated.

To obtain a more physiologically realistic picture of how the perilipin PKA site phosphorylation regulates adipocyte lipolysis, we developed a stable line of retrovirally engineered perilipin null (Peri^–/–) adipocytes from MEFs of perilipin knock-out mice (20). These MEF adipocytes exhibit biochemical and physiological hallmarks of true adipocytes (20). Importantly, these MEF adipocytes robustly express both HSL (20) and ATGL (see "Results"). Expression of wild type Peri A fully supports PKA-stimulated lipolysis in these Peri^–/– MEF adipocytes, whereas expression of a mutant Peri A lacking all six functional PKA sites (1–6) fails to support PKA-stimulated lipolysis (20). It is unknown whether Peri A mediates lipase-selective regulation of adipocyte lipolysis and, if so, how phosphorylation of different Peri A PKA sites hierarchically structures and spatiotemporally coordinates this regulation.

Using adenoviral expression of Peri A PKA site mutants, we now demonstrate that serine 517 (PKA site 6) globally regulates all PKA-stimulated FA and glycerol release in MEF adipocytes. Small hairpin RNA (shRNA)-mediated "knockdown" of ATGL and HSL reveals that this regulation reflects the absolute necessity of serine 517 phosphorylation for ATGL-mediated lipolysis in response to PKA activation. These observations provide the first evidence that Peri A regulates ATGL-mediated lipolysis. Moreover, we identify serine 517 as a novel master regulator of PKA-dependent Peri A functions regulating hormone-stimulated lipolysis in adipocytes.

	EXPERIMENTAL PROCEDURES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Materials—A specific polyclonal anti-rabbit ATGL antibody was generated using the peptide CTNVAFPPDALRMRAPAS. Antibodies were subsequently affinity-purified and used for Western blotting (1:2000).

Generation and Differentiation of Stable Lines of Peri^–/– MEF Adipocytes—Stable lines of MEFs were generated from embryos of Peri^–/– mice as described (20, 31). MEF adipocytes were generated by retroviral expression of peroxisome proliferator-activated receptor (31) followed by selection, expansion, and differentiation using a standard differentiation medium (20). MEF adipocytes attained a differentiated adipocyte phenotype within 7 days of culturing in differentiation medium (20).

Peri A Truncations and PKA Site Mutants—Adenoviruses expressing the following constructs were generated and verified as previously described (16, 20) (see Fig. 1A): Aequorea victoria green fluorescent protein (GFP), Peri A containing serine alanine mutations at either all six PKA sites (1–6), N-terminal PKA sites (1–3), C-terminal PKA sites (4–6), or individual PKA sites (1, 2, 3, 4, 5, and 6), and Peri A containing a serine aspartic acid mutation at PKA site 6 (6D).

Adenoviral Expression of Peri A Constructs in Peri^–/– MEF Adipocytes—Recombinant adenovirus was transduced into Peri^–/– MEFs with Lipofectamine Plus^TM (Invitrogen) on day 2 (adenovirus shRNAs) or day 3 (all other adenovirus) after induction of differentiation. The amount of each adenovirus used was selected to assure comparable levels of expression of the different Peri A constructs, which was confirmed by Western blots and densitometry (16, 20).

Recombinant Adenoviruses Expressing shRNA Directed against Murine ATGL or HSL—ATGL shRNA design was based on accession number NM025802 (sequence GGAGAGAACGTCATCATAT). HSL shRNA design was based on accession number NM010719 (sequence GCAAGAGTATGTCACGCTA). A "scrambled" version of these shRNAs (CGCGCTTTGTAGGATTCA) was generated as a control for nonspecific effects of shRNA on lipolysis. All shRNAs were cloned into the pQuiet vector to generate recombinant adenoviruses.

Lipolysis Assays—Glycerol and fatty acid release were quantified after 2 h of treatment with/without the PKA activator forskolin (20 µM) as described (15, 20).

Quantitative PCR—Total RNA was extracted from Peri^–/– MEF cells at days 0, 3, 5, and 7 of differentiation into adipocytes and from 3T3-L1 fibroblasts (16) using a commercial kit (Invitrogen). RNA was quantified by RiboGreen Quantitation Assay (Molecular Probes, Eugene, OR), and cDNA was synthesized from 1 µg of total RNA (Reverse Transcription System, Promega). Real-time PCR was performed in triplicate on an ABI PRISM® 7700 in a 20-µl total volume using SYBR® Green PCR Master MIX (Applied Biosystems, Foster City, CA). Primers were designed using Primer Express. Data were analyzed by comparative critical threshold (Ct) method and normalized to an endogenous control gene (18 S ribosomal RNA) (32). Percent difference was calculated by 2^–Ct.

Immunofluorescence Microscopy—After serum depletion, cells were treated for 2 h with either 200 nM N⁶-phenylisopropyladenosine (PIA) to repress adenyl cyclase activity (basal condition) or with 20µM forskolin (stimulated condition) followed by fixation and incubation with perilipin antibody (16). Images were acquired with a Leica TCS SP2 confocal microscope equipped with an acoustico-optical beam splitter.

View larger version (26K): [in this window] [in a new window]   FIGURE 1. Phosphorylation of one or more Peri A C-terminal PKA sites is essential for PKA-stimulated lipolysis in MEF adipocytes. A, diagram of Peri A and Peri A truncations, indicating the relative positions of serine residues of the six consensus PKA phosphorylation sites. B, PKA-stimulated lipolysis (glycerol release) is abrogated by serine alanine mutation of Peri A PKA sites 1–6 (1–6) and 4–6 (4–6) and partially blocked by mutation of PKA sites 1–3 (1–3). Peri–/– MEF cells were transduced with adenovirus expressing GFP (negative control), Peri A, or mutated Peri A. After differentiation to adipocytes, cells were depleted of serum and treated for 2 h in the absence (–, open bars) or presence (+, shaded bars) of the PKA activator forskolin (20 µM). The medium was collected, and glycerol content was determined. Data (mean ± S.E.) are from 3–7 experiments performed in at least duplicate and are normalized to PKA-stimulated lipolysis in cells expressing Peri A. Lower panel, Western blot with anti-perilipin IgG (15) showing comparable levels of adenovirus-expressed proteins in a representative experiment. **, p < 0.01.

Statistical Analysis—Data are reported as the mean ± S.E. Treatment effects were analyzed by analysis of variance using Tukey's procedure for multiple comparisons (Systat Version 10 for Macintosh, SAS Institute). Significance was set at p < 0.05. Percentage data (Table 1) were transformed as arcsin x before analysis (33).

	RESULTS

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

Selective Mutation of Serine 517 (PKA Site 6) Abrogates PKA-stimulated Lipolysis in MEF Adipocytes—To identify the C-terminal PKA sites that are essential for PKA-stimulated lipolysis, we conducted lipolysis assays with full-length Peri A constructs containing individual serine to alanine mutations at PKA sites 4(4), 5(5), or 6(6). Surprisingly, mutation of site 6 alone (6) was sufficient to fully abrogate PKA-stimulated lipolysis (Fig. 2A), thereby recapitulating the inhibitory effects of both 1–6 and 4–6 (Fig. 1B). Thus, functional PKA sites 1–5 are insufficient to promote any PKA-stimulated increase in lipolysis in the absence of serine 517 phosphorylation. This result indicates that serine 517 is essential for PKA-stimulated lipolysis.

Adenoviral expression of 5 containing a mutant serine 492 (PKA site 5) resulted in partial (30%) inhibition of PKA-stimulated lipolysis (Fig. 2A), indicating that in the presence of phosphorylated serine 517 (and PKA sites 1–3), serine 492 enhances PKA-stimulated lipolysis. In contrast, mutation of PKA site 4 had no effect on PKA-stimulated lipolysis (Fig. 2A).

Adenoviral expression of full-length Peri A constructs containing serine to alanine substitutions at individual N-terminal PKA sites 1(1), 2(2), or 3(3) failed to diminish PKA-stimulated lipolysis as compared with wild type Peri A (Fig. 2B). Because mutation of all three N-terminal PKA sites (1–3) partially attenuated PKA-stimulated lipolysis (Fig. 1B), these results indicate that Peri A N-terminal PKA sites enhance PKA-stimulated lipolysis by a mechanism requiring phosphorylation of at least two of the three sites. As observed for PKA site 5, this mechanism promotes PKA-stimulated lipolysis only in the presence of phosphorylated serine 517 (Fig. 2A).

Serine 517 (PKA Site 6) Regulates PKA-stimulated Lipolytic Actions of ATGL—Consistent with their differentiated adipocyte phenotype, Peri^–/– MEF adipocytes robustly express both HSL (20) and ATGL (Fig. 3A), the rate-limiting lipase for TAG catabolism in adipocytes (28). To determine the relative contribution of ATGL to PKA-stimulated lipolysis in MEF adipocytes, we measured PKA-stimulated FA and glycerol release from MEF adipocytes in the presence and absence of ATGL-directed shRNA (Fig. 3B). ATGL-directed shRNA reduced ATGL protein expression by 100%, and this reduction was coincident with total abrogation of forskolin-induced FA release (Fig. 3B, upper panel). Note that a small increment of PKA-stimulated FA release is Peri A-independent (observed in GFP-expressing cells) and that this Peri A-independent lipolysis is also blocked by ATGL-directed shRNA. In addition to its inhibitory effect on FA release, ATGL-directed shRNA completely blocked forskolin-induced glycerol release (Fig. 3B, lower panel). This result is consistent with the view that ATGL is the initiator TAG lipase upstream of HSL and that HSL acts exclusively on DAG in MEF adipocytes (24, 26). Thus, ATGL lipolytic activity is required for essentially all lipolysis in MEF adipocytes. This predominant role of ATGL in PKA-stimulated lipolysis strongly suggested that mutation of serine 517 of Peri A abrogates PKA-stimulated lipolysis (Fig. 2A) by blocking ATGL lipolytic action at the LD surface.

View larger version (20K): [in this window] [in a new window]   FIGURE 2. Phosphorylation of serine 517 is essential for PKA-stimulated glycerol release. A, upper panel, PKA-stimulated lipolysis is fully supported by Peri A containing a mutant PKA site 4 (4), partially inhibited by a Peri A containing mutant PKA site 5 (5), and completely inhibited by Peri A containing a mutant PKA site 6 (6). Lipolysis assays (2 h) were conducted in the absence (–, open bars) or presence (+, shaded bars) of the PKA activator forskolin (20 µM). Data are from three experiments performed in at least duplicate. Lower panel, representative Western blot with anti-perilipin IgG (15). B, individual N-terminal PKA site mutants (1, 2, or 3) fully support PKA-stimulated lipolysis. Data are from five experiments performed in at least duplicate. Lower panel, representative Western blot with anti-perilipin IgG (15). **, p < 0.01.

To assess whether phosphorylation of serine 517 is sufficient for PKA-stimulated lipolysis, we generated a phosphomimetic charge mutant by substituting aspartic acid for serine 517 (6D). We reasoned that if phosphorylation of serine 517 was sufficient to promote PKA-stimulated lipolysis, expression of Peri A6D in Peri^–/– MEF adipocytes would stimulate lipolysis in the absence of PKA activation. Expression of 6D in Peri^–/– MEF adipocytes resulted in a significant (35%) enhancement of PKA-stimulated FA release relative to wild type Peri A (p < 0.05; Fig. 4). However, expression of 6D had no detectable effect on basal state release of fatty acids (Fig. 4) or glycerol (data not shown). Thus, the presence of an acidic residue at position 517 of Peri A results in a significantly enhanced lipolytic response to PKA but does not increase lipolysis in the absence of PKA activation.

Effects of Peri A PKA Site Mutants on Lipid Droplet Dispersion—PKA activation induces the fragmentation of LDs into small Peri A-coated microdroplets, which disperse throughout the cytoplasm. This LD dispersion is implicated in the regulation of PKA-stimulated lipolysis (19, 34–36). Although serine 492 (PKA site 5) is reported to regulate PKA-induced LD dispersion, the role of serine 517 phosphorylation in this process has not been addressed (19). Accordingly, we asked if the requirement of serine 517 phosphorylation for PKA-stimulated lipolysis reflected an essential role for serine 517 in LD dispersion. Using Peri A immunofluorescence and confocal microscopy, we graded forskolin-induced (2 h) LD dispersion in MEF adipocytes expressing either wild type Peri A or the PKA site mutants 6, 6D, and 5 (see "Experimental Procedures"). LDs were graded as either clustered (no dispersion) or dispersed (either partially or fully). These data are summarized in Table 1, with representative confocal images presented in Fig. 5.

View larger version (24K): [in this window] [in a new window]   FIGURE 3. Serine 517 globally regulates PKA-stimulated lipolysis by regulating ATGL. A, ATGL gene expression is up-regulated 85-fold during the differentiation of Peri–/– MEF adipocytes. mRNA levels (ATGL/18 S) were quantitated by SYBR Green real-time PCR and expressed relative to levels measured at day 7. Note the negligible ATGL expression in 3T3-L1 fibroblasts. Lower panel, representative Western blot with anti-ATGL IgG. B, shRNA knockdown of ATGL abrogates all PKA-stimulated release of FAs (upper panel) and glycerol (lower panel). Peri–/– MEFs were transduced with adenovirus expressing either GFP (control) or Peri A in conjunction with either ATGL-directed shRNA or scrambled shRNA (see "Experimental Procedures"). Results are expressed as the mean ± S.E. of four experiments performed in at least duplicate. Representative Western blots are with anti-ATGL IgG and anti-perilipin IgG (15). **, p < 0.01. C, residual lipase activity after shRNA knockdown of HSL is fully blocked by mutation of serine 517 (6). MEF adipocytes received either HSL-directed shRNA or scrambled shRNA. Lower panel, representative Western blots with anti-HSL IgG (41) and anti-perilipin IgG. **, p < 0.01.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 
Peri A is the "gatekeeper" of adipocyte TAG storage and hydrolysis. Consistent with this physiological function, Peri A polymorphisms and protein levels are associated with risk for obesity and insulin resistance (37, 38). How Peri A regulates TAG storage and hydrolysis in adipocytes remains controversial (20, 39). The present study exploits a novel adipocyte model system derived from Peri^–/– MEFs to investigate how phosphorylation of Peri A PKA sites regulate hormone-stimulated lipolysis in adipocytes. As in murine adipocytes in vivo (24, 28), Peri A^–/– MEF adipocytes express both ATGL and HSL, with PKA-dependent TAG hydrolysis initiated by and dependent upon ATGL (Figs. 3, B and C). This initiator function of ATGL renders it rate-controlling for lipolysis in mouse adipocytes (27, 28). Here, we demonstrate for the first time that the ability of Peri A to globally regulate PKA-stimulated lipolysis in adipocytes reflects Peri A-dependent regulation of ATGL lipolytic function. Moreover, we identify phosphorylation of serine 517 of Peri A as essential for ATGL-mediated (and thus HSL-mediated) adipocyte lipolysis in response to PKA activation. Mutation of serine 517 to alanine is sufficient to completely abrogate PKA-stimulated FA and glycerol release to levels observed in the absence of Peri A (Fig. 2A) or in the presence of PKA site-deficient Peri A (1–6, Fig. 1B). These data are the first to identify a role for serine 517 in lipolysis and provide the first demonstration that adipocyte lipolysis can be acutely and globally regulated by a single Peri A amino acid.

To address the mechanism of serine 517 action, we asked if phosphorylation of serine 517 was required for PKA-stimulated LD dispersion, an event implicated in PKA-stimulated lipolysis (19, 34–36). The almost negligible effect of serine 517 mutation on PKA-stimulated LD dispersion (Table 1) strongly suggests that serine 517 regulates ATGL-mediated lipolysis by a mechanism other than LD dispersion. However, our data do not rule out the possibility that serine 517 phosphorylation alters LD structure on a scale below the resolution of the studies reported here and that this alteration in LD structure is required for ATGL-mediated lipolysis. With regard to mechanism, Peri A is currently viewed as a component of a dynamic scaffold that serves as an LD-associated organizing center for enzymes and transporters involved in lipid metabolism (40). Metabolically regulated changes in the conformation and composition of this scaffold are proposed to inhibit or promote lipolysis. In this context, serine 517 phosphorylation may function as an electrostatic or conformational "switch" that regulates the selective interaction of ATGL and/or modulators of ATGL function (27) with LDs. Elucidation of how serine 517 phosphorylation alters the LD "interactome" to facilitate ATGL-mediated lipolysis will provide critical insight into the molecular mechanism(s) of TAG storage and hormone-stimulated lipolysis in adipocytes.

View larger version (17K): [in this window] [in a new window]   FIGURE 4. 6D, a phosphomimetic (serine aspartic acid) substitution at serine 517, does not constitutively elevate basal lipolysis but does promote enhanced PKA-stimulated lipolysis over that obtained with wild type Peri A. Lipolysis assays were conducted as in Fig. 1. Results are expressed as mean ± S.E. of three experiments performed in at least duplicate. Lower panel, representative Western blots with anti-perilipin IgG. **, p < 0.01.

View larger version (98K): [in this window] [in a new window]   FIGURE 5. Serine 517 regulates PKA-stimulated lipolysis independently of LD dispersion. Peri–/– MEFs were transduced with adenovirus and differentiated to adipocytes. After serum depletion, MEF adipocytes were treated for 2 h with either 200 nM N6-phenylisopropyladenosine (basal condition) or with 20 µM forskolin (stimulated condition) followed by fixation and incubation with anti-perilipin IgG (see "Experimental Procedures"). A and B, in cells expressing Peri A, LDs are aggregated under basal conditions but are disrupted into microdroplets that are dispersed throughout the cell in response to PKA activation. C and D, a similar pattern of PKA-induced LD disruption is predominant among cells expressing the serine 517 mutant, 6 (see also Table 1). E and F, in contrast, 40% of cells expressing the serine 492 mutant, 5, exhibit aggregated LDs in response to forskolin. Scale bar, 10 µm.

In the present study mutation of PKA sites 1–3 partially blocked PKA-stimulated glycerol release and, thus, HSL action, consistent with prior studies demonstrating a role for sites 1–3 in promoting HSL-mediated lipolysis (15–18). We demonstrate for the first time that, in contrast to PKA sites 6 and 5, mutation of individual PKA sites (1, 2, or 3) has no effect on lipolysis (Fig. 2B), indicating that Peri A N-terminal PKA sites modulate HSL-mediated lipolysis via a multisite mechanism. This mechanism is not required for PKA-induced LD dispersion in MEF adipocytes (data not shown) or in fibroblasts (19), but it may promote tight binding of HSL with the LD surface (20). Irrespective of the exact mechanism by which PKA sites 1–3 promote HSL-mediated lipolysis, the mechanism is insufficient to promote any PKA-stimulated lipolysis in the absence of serine 517 phosphorylation. This may in part reflect the unavailability of DAG (the preferred HSL substrate) in the absence of ATGL-dependent TAG hydrolysis. The involvement of Peri A PKA sites 1–3 and 5 in hormone-stimulated lipolysis raised the possibility that serine 517 is required for phosphorylation of these sites. However, mutation of serine 517 to alanine does not inhibit PKA-dependent phosphorylation of these other PKA sites (PKA 1–5) (supplemental Fig. 1). Elucidation of the molecular mechanism underlying lipolytic regulation by serine 517 remains an exciting challenge for future studies.

Considered together, these observations support the designation of serine 517 of Peri A as a master regulator of PKA-dependent lipolysis and identify ATGL as a critical target of serine 517 action. The primacy of serine 517-dependent regulation among the multiple lipolytic regulatory mechanisms in MEF adipocytes reflects the function of ATGL as the initiator lipase in TAG hydrolysis. A similar function for ATGL is reported for mouse adipocytes (28), suggesting that serine 517 globally regulates PKA-stimulated lipolysis in vivo.

	FOOTNOTES

 
^* This work was supported by National Institutes of Health Grant DK-50647 and United States Department of Agriculture Agricultural Research Service Co-Operative Agreement 58 1950-4-401 (to A. S. G.), National Institutes of Health Grant AG024635, Center for Digestive Disease Research, National Institutes of Health Grant P30 DK-34928, and American Diabetes Association Grant 1-06-RA-96 (to M. S. O.), Tufts Center for Neuroscience Research National Institutes of Health Grant P30 NS047243, GRASP (Center for Gastroenterology Research on Absorptive and Secretory Processes) Center P30 DK-34928, and the Research Service of the Department of the Veterans Affairs (to F. B. K.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The on-line version of this article (available at http://www.jbc.org) contains supplemental Fig. 1.

¹ To whom correspondence may be addressed: JMUSDA-HNRCA at Tufts, 711 Washington St., Boston MA 02111. Tel.: 617-556-3079; Fax: 617-556-3224; E-mail: martin.obin{at}tufts.edu. ² To whom correspondence may be addressed: JMUSDA-HNRCA at Tufts, 711 Washington St., Boston MA 02111. Tel.: 617-556-3144; Fax: 617-556-3224; E-mail: andrew.greenberg{at}tufts.edu.

³ The abbreviations used are: TAG, triglyceride; ATGL, adipose triglyceride lipase; DAG, diacylglycerol, FA, fatty acid; GFP, green fluorescent protein; HSL, hormone sensitive lipase; LD, lipid droplet; MEF, murine embryonic fibroblast; Peri A, perilipin A; 1–6, Peri A mutant containing serine to alanine mutations at PKA sites 1–6; 1–3, Peri A mutant containing serine to alanine mutations at PKA sites 1, 2 and 3; 4–6, Peri A mutant containing serine to alanine mutations at PKA sites 4,5 and 6; 1, 2, 3, 4, 5, 6, Peri A mutants containing an individual serine to alanine mutation at PKA site 1, 2, 3, 4, 5, or 6; Peri A6D, Peri A mutant containing an aspartic acid substitution for serine at PKA site 6; shRNA, small hairpin RNA; MEF, murine embryonic fibroblast; PKA, protein kinase A.

	ACKNOWLEDGMENTS

 
H. M. thanks Professor Takao Koike for continued support and mentorship.

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TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

 

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