Enzymatic activity of the human 1-acylglycerol-3-phosphate-O-acyltransferase isoform 11: upregulated in breast and cervical cancers.

The conversion of lysophosphatidic acid (LPA) to phosphatidic acid is carried out by the microsomal enzymes 1-acylglycerol-3-phosphate-O-acyltransferases (AGPATs). These enzymes are specific for acylating LPA at the sn-2 (carbon 2) position on the glycerol backbone and are important, because they provide substrates for the synthesis of phospholipids and triglycerides. At least, mutations in one isoform, AGPAT2, cause near complete loss of adipose tissue in humans. We cloned a cDNA predicted to be an AGPAT isoform, AGPAT11. This cDNA has been recently identified also as lysophosphatidylcholine acyltransferase 2 (LPCAT2) and lyso platelet-activating factor acetyltransferase. When AGPAT11/LPCAT2/lyso platelet-activating factor acetyltransferase cDNA was expressed in CHO and HeLa cells, the protein product localized to the endoplasmic reticulum. In vitro enzymatic activity using lysates of Human Embryonic Kidney-293 cells infected with recombinant AGPAT11/LPCAT2/lyso platelet-activating factor-acetyltransferase cDNA adenovirus show that the protein has an AGPAT activity but lacks glycerol-3-phosphate acyltransferase enzymatic activity. The AGPAT11 efficiently uses C18:1 LPA as acyl acceptor and C18:1 fatty acid as an acyl donor. Thus, it has similar substrate specificities for LPA and acyl-CoA as shown for AGPAT9 and 10. Expression of AGPAT11 mRNA was significantly upregulated in human breast, cervical, and colorectal cancer tissues, indicating its adjuvant role in the progression of these cancers. Our enzymatic assays strongly suggest that the cDNA previously identified as LPCAT2/lyso platelet-activating factor-acetyltransferase cDNA has AGPAT activity and thus we prefer to identify this clone as AGPAT11 as well.

mol/L oleoyl CoA (Sigma, St. Louis, MO), 1 l of [ 3 H] oleoyl-LPA (specifi c activity 30-60 Ci/mmol; PerkinElmer Life and Analytic Sciences, Boston, MA), and 1 mg/ml fatty acid free BSA. The reaction was started by adding 30 g of cell lysate followed by incubation for 10 min at 37°C. The reaction was terminated by adding 0.5 ml of 1-butanol containing 1 NHCl and to extract phospholipids. The butanol extract was dried under vacuum and the LPA and PA were resolved using the solvent system: chloroform-methanolacetic acid-water (85:12.5:12.5:3). Radioactive spots were identifi ed by co-migration with unlabeled LPA and PA standard and visualized in iodine vapors. The The acyltransferase activity for additional lysophospholipids, LPE, LPG, LPI , and LPS, all containing the C18:1 fatty acid at the sn-1 position, were determined by substituting these lysophospholipids for LPA.

Acyl-CoA specifi city
The specifi city of esterifi cation of sn -2 position of [

GPAT assay
GPAT activity was determined as described earlier ( 9 ). Briefl y, Huh7 cells depleted of AGPAT2 expression by shRNA were infected with recombinant adenoviruses expressing either GPAT1 or AGPAT11 at a multiplicity of infection of 150, and the cell lysate was prepared as described above. The enzyme reaction was assembled by adding 60 M acyl-CoA, 150-800 M glycerol-3phosphate (G-3-P) , spiked with either [ 14 C] glycerol-3-phosphate (American radiolabels) or [ 14 C]oleoyl CoA (Perkin Elmer) in a buffer mix consisting of 75 mM Tris, pH 7.4, 2 mg/ml BSA, 4 mM MgCl 2 , and 2 mM DTT in total volume of 200 l. The enzymatic reaction was started by adding 100 g of cell lysate and further incubated for 20 min at room temperature. The lipid extraction procedure was the same as for the acyltransferase assay. The product formed (LPA) was resolved on TLC using the following solvent system: chloroform:methanol:acetic acid:H 2 O (50:25:8:4). G-3-P and LPA spots were identifi ed by exposure to iodine, scraped, and quantifi ed. In some assays, PA spots were also counted for erroneous AGPAT activity.

Western blot analysis
Cells overexpressing V5-tagged AGPAT11 were collected and lysed in RIPA buffer containing protease inhibitor cocktail METHODS Generation of V5-epitope-tagged wild-type AGPAT11 recombinant adenovirus The strategy for generating recombinant adenovirus using the AdEasy adenoviral system (Stratagene, La Jolla, CA) has been described previously ( 9 ). Briefl y, the full-length open reading frame (ORF) AGPAT11 cDNA was tagged with V5-epitope at the aminoterminus by amplifying the cDNA from a plasmid containing the ORF for AGPAT11 (the details for the generation of the cDNA for human AGPAT11 are described in the supplementary material provided with this manuscript), with primers 5 ′ -GCGTCGAC-ATG GGTAAGCCTATCCCTAACCCTCTCCTCGGTCTCGAT-TCTACG AGCCGGTGCGCCCAG -3 ′ ; the V5 epitope is underlined, and 5 ′ -CGCTCGAGTCAGTCATCTTTTTTGTCTGAGG-TAC-3 ′ . The amplifi ed product was cloned in TA-cloning vector, sequenced, restriction digested with Xho I, and cloned in the pShuttleCMV vector at the same site. The orientation of the insert was confi rmed by restriction digest and sequencing of the plasmid. To generate recombinant adenovirus, the pShuttle-CMV-AGPAT11 plasmid was digested with Pme I and cotransformed with pAdEasy-1 into BJ5183 cells. The recombinant AdEasy-1-AGPAT11 plasmid was digested with Pac I and transfected in AD293 cells using Lipofectamine-2000. Several viral pools were further propagated in the same AD293 cells. The viral pool that showed most enzymatic activity was selected for further amplifi cation and purifi cation using the Virabind adenovirus purifi cation kit (Cell Biolabs Inc., San Diego, CA). The generation of recombinant adenovirus-␤ -galactosidase has been described previously ( 9 ).

Generation of EGFP-tagged wild-type AGPAT11 expression vector
The construction of the wild-type AGPAT11-GFP fusion protein was carried out using the AGPAT11 cloned in TA cloning vector. The ORF for AGPAT11 was amplifi ed using wild-type plasmid as the template and primer pair 13 and 14 (supplementary Table I ). The amplifi ed product and the plasmid pEGFP-N3 (Clontech, Mountain View, CA) were restricted with Xho I and Bam HI and cloned in the similar sites. The expression plasmid was sequenced to ascertain the orientation and the correctness for the junction sequences.

AGPAT enzymatic activity of AGPAT11 in the cell lysate
For all enzymatic assays, the adenoviral expressed recombinant protein was used. The AD293 cells were infected with AG-PAT11 recombinant adenovirus at a multiplicity of infection of 150. It is to be noted that the method employed for the virus purifi cation yielded low level of infectious viral particle. After 48 h, the infected cells were collected and washed once with PBS. The viral pellet was resuspended in the lysis buffer (100 mM Tris, pH 7.4, 10 mM NaCl containing protease inhibitor cocktail, Roche, Indianapolis, IN). The cells were lysed in two different ways: fi rst with three freeze-thaw cycles and second via sonication which was carried out at 65% output (which generates energy of 20 J) for three 6 s bursts with intermittent cooling on ice (Sonics Vibra Cell, Danbury, CT). The cell lysate was centrifuged at 3,000 g for 10 min at 4°C to remove the cell debris. Protein concentration was determined by a commercially available colorimetric assay (Bio-Rad Laboratories, Hercules, CA).
The enzyme activity was determined by measuring the conversion of tritiated lysophosphatidic acid [

Total RNA isolation and reverse transcription
The cultured cells were lysed in RNA Stat-60 (Tel-Test, Inc., Friendswood, TX). Similarly, the normal and carcinoma tissues were homogenized in RNA Stat-60 to obtain total RNA as suggested by the manufacturer. A known quantity of total RNA (1 g) was treated with DNase I to remove residual DNA, and the RNA was reverse transcribed with omniscript RT kit following the manufacturer's protocol (Qiagen) in a total volume of 20 l. The expression of AGPAT11 was quantifi ed using Assay on Demand TaqMan Master Mix from ABI (primer/probe set Hs00215225_ml).

Statistical analysis
All quantitative enzymatic data are shown as mean ± SD. P -values were obtained using a Student's t -test. Statistical analyses were performed using the SAS version 9.13 (SAS Institute, Cary, NC).

Tissue distribution and quantitative expression in human tissue panel
The northern blot analysis detected two mRNA of approximate sizes close to 4 and 5 kb in heart, skeletal muscle, and peripheral leukocyte (supplementary Fig. I ). We expanded our search for expression in human tissues by using cDNA and quantifi ed using real-time PCR. Shown in Table 1 are the ⌬ Ct values for various tissues after being normalized to the housekeeping gene G3PDH . In this tissue panel, the highest expression was detected in the lung and the leukocytes, with slightly decreased expression in the spleen and adipose tissue. The multiple protein alignment of known AGPATs reveals that human AGPAT11 is very close to the human AGPAT9 ( Fig. 1A ). The mRNA expression data for the two isoforms, AGPAT9/LPCAT1, which we reported earlier (8), and AGPAT11/LPCAT2 (this study), are also similar to what we reported previously. Quantitative real-time PCR revealed that the two isoforms have very similar expression patterns for most tissues in humans, except that AGPAT11/LPCAT2 is expressed 1-to 2-fold less than AGPAT9/LPCAT1. However, in the lung, spleen, and leukocytes, AGPAT11 is expressed 5-to 6-fold less than the AGPAT9.

Comparison with other known AGPATs
Multiple sequence alignment of the known human AG-PATs revealed that AGPAT11 was more similar to AGPAT9 (Roche, Indianapolis, IN). Lysates were centrifuged at 1,000 g for 10 min to remove cellular debris to obtain the fraction containing mitochondria, microsomes, and cytosol (WCL ). The supernatant was further fractionated into mitochondria, microsomes, and cytosol by differential centrifugation. Protein concentrations were determined using Bio-Rad DC protein assay (BioRad, Hercules, CA). Total protein (50 g) from each fraction was resolved on 10% SDS-PAGE followed by transfer onto nylon membrane (Millipore, Billerica, MA). The membrane was blocked with 5% non-fat milk containing 0.2% Tween-20 and then incubated with V5 antibody (dilution 1:5,000) conjugated to horseradish alkaline phosphatase (Invitrogen) for 2 h at room temperature. The membrane was washed and then incubated with ECL reagent (GE Healthcare Piscataway, NJ) and exposed to X-ray fi lm to visualize the immunoreactive protein. The same blots were stripped using the restore, a Western blot stripping buffer (Pierce, Rockford, IL), according to the manufacturer's protocol, reprobed with anti-GAPDH antibody at a dilution of 1:5,000, and detected with IgG conjugated with horseradish peroxidase at a dilution of 1:5,000.

Immunofl uorescence microscopy
Stably expressing AGPAT11-EGFP CHO cells were grown on cover slips 1 day before the experiment. HeLa cells were plated on cover slips in a 6-well plate and transiently transfected with 1.5 g of AGPAT11-EGFP 24 h before the experiment. Cells were fi xed/permeabilized by incubation with methanol ( Ϫ 20°C) for 20 min. Cells were washed 3 × 5 min with PBS and then incubated with primary antibody (Sec61 ␤ at a diluted of 1:200, Upstate, Lake Placid, NY) for 30 min at 37°C in a humidifi ed chamber. Cells were then washed 3 × 5 min with PBS and incubated with AlexaFluor 598 coupled fl uorescent secondary antibody (Invitrogen) for 30 min at 37°C in a humidifi ed chamber. After incubation, cells were washed 3 × 5 min with PBS, counter stained with 4'-6-diamidino-2-phenylindole during the washes and mounted on a glass slide with Aqua Poly/Mount (Polysciences, Inc., Warrington, PA). Cells were observed with DeltaVision RT Deconvolution Microscope (Applied Precision, LLC; Issaquah, WA).

Quantitative real-time PCR in human tissue panel
Quantitative PCR was performed using the TaqMan primer and probes and designed using primer express software, ABI PRISM 7700 sequence detection system, and PRIMER EXPRESS analysis software ( 13 ) using the human cDNA panel from Clontech (Palo Alto, CA). To amplify AGPAT11, 100 pg of cDNA was added to the forward (5 ′ -CACTCTTTGACAGGAACCATGATG-3 ′ ) and reverse (5 ′ -ACAGCCAGGCCAATCACATAC-3 ′ ) primers along with famlabeled probe (CAGCATTGACTTCCG) and universal mix containing AmpliTaq and appropriate buffers. The PCR was followed for 40 cycles of 94°C for 15 s and 60°C for 30 s. The cDNA was amplifi ed in duplicate along with G3PDH as an internal control. The ⌬ Ct value for each tissue was calculated as ⌬ Ct = [Ct (tissue) Ϫ Ct (G3PDH)] where necessary.

Human tissues and cell lines
To determine the expression of AGPAT11 in various carcinomas, we used cultured cells derived from the human colon, breast, and cervix cancer tissues, as well as human carcinoma tissues. The HEK293, T84, HT-29, SW480, SW620, CaCo-2, MCF-7, and MDAMB231 were from ATCC (Manassas, VA). All cells were cultured in DMEM supplemented with 10% serum and antibiotics, except HT-29, which was cultured in McCoy's 5a medium, SW480, and SW620 in Leibovitz's L-15 medium and T84 in DMEM/F12 1:1 medium. The human tissues were obtained through The Cooperative Human Tissue Network, Southern Division, University of Alabama at Birmingham, Birmingham, AL.  ␤ -galactosidase. Most likely, this was due to excessive background (data not shown). We then generated recombinant adenovirus expressing AGPAT11 and expressed it in the AD293 cells. To determine the expression of AGPAT11 protein, the cell lysates were fractionated into subcellular fractions and subjected to Western blot analysis. As shown in Fig. 3A the expression of AGPAT11 could be recovered in both the mitochondria and microsomes, but not in the cytosol fraction. Immunofl uorescence localization of AG-PAT11 did not reveal that the protein localizes to the mitochondria other than the ER. This could be due to a couple of reasons: it could be an artifact of the overexpression of the recombinant adenovirus in AD293 cells, or, alternatively, it could be the feature of the host cells. When the enzymatic activity was determined in various cellular fractions, only the microsomal fraction showed signifi cant AGPAT activity ( Fig. 3B ).
Because we observed AGPAT activity for AGPAT11 in microsomes and its detection in mitochondria by Western blot, for all further enzymatic assays we employed postnuclear fraction. We then performed preliminary optimization for the AGPAT enzymatic activity. First, the cells were subjected to either freeze-thaw or only sonication of the cellular lysate and determined the AGPAT activity. As shown in Fig. 4A , the sonicated lysate retained much more than any other acyltransferases within the family ( Fig. 1A ). The two isoforms are 58% homologous and 41.5% identical at the amino acid level. The signature motifs involved in catalytic and substrate binding, NHX 4 D and EGTR, are conserved in all the phospholipid acyltransferases. However, alignment of AGPAT11 human isoform with mouse and zebrafi sh showed that the arginine residue in the EGTR motif is substituted by cysteine, and in motif NHX 4 D, the asparagine is substituted with proline ( Fig. 1B ).

Subcellular localization of AGPAT11-GFP
In CHO cells stably expressing the human AGPAT11-GFP fusion protein, fl uorescence microscopy showed an endoplasmic reticulum (ER)-like expression pattern. This subcellular localization was confi rmed by colocalizing AG-PAT11-GFP with the ER-specifi c protein sec61-␤ ( Fig. 2 ). The subcellular localization was further confi rmed in HeLa cells, except that the cells were transiently transfected with the AGPAT11-GFP construct, which again localized to ER ( Fig. 2 ).

AGPAT activity
We initially created stable CHO cells expressing AG-PAT11. However, we were unable to detect any significant AGPAT activity compared with those expressing Because the LPA with C18:1 fatty acid retained significant enzymatic activity, we used this LPA as the acyl acceptor to determine the specifi city of various acyl-CoA. The panel consists of fatty acids from C8:0 to C26:0, including some with unsaturated fatty acid. The preferred acyl donor was in the order of C18:1 > C16:0 > C18:2 > C17:0. Fatty acids consisting of short-chain carbon: C8:0 to C13:0 and very long-chain from C20:0 to C26:0 retained no enzymatic activity ( Fig. 5B ). There also appeared to be an upper limit for the C18 fatty acid unsaturation. The acyl-CoA (C18:3) consisting of three double bonds did not acylate the LPA to PA.
We employed various other lysophospholipids, LPS, LPE, LPI, and LPG, to ascertain whether AGPAT11 could esterify these phospholipids. AGPAT11 did not show any signifi cant acyltransferase activity above the background for LPG, LPE, or LPI. LPS is the only other lysophospholipid for which AGPAT11 retained some enzymatic activity, but is not as robust as when LPA is the acyl acceptor ( Fig. 6A ). We then investigated if the AGPAT11 has any AGPAT activity than the freeze-thaw. We then determined enzymatic activity of the cell lysate obtained by sonicating either freshly prepared or frozen cell lysate. In our hands, there was no signifi cant difference between the two processing methods ( Fig. 4B ). Therefore, for all the enzymatic activity assays, we used cellular lysate obtained by sonication of frozen lysates for ease of the experiments ( Fig.  4C ).

Substrate specifi city of AGPAT11
Because human AGPAT11 revealed AGPAT activity, we then determined its acyl-CoA and LPA specifi city. We employed a panel of LPAs with various long-chain fatty acids at the sn-1 position and using oleoyl-CoA to determine the AGPAT activity as shown in Figure 5A . AGPAT11 appears to have broader preferences for the LPA containing saturated fatty acids C16:0-C18:0, including LPA containing monounsaturated fatty acid (C18:1). LPA with fatty acid C20:4 is acylated at only about one-half maximal rate compared with other LPAs.  Fig. 4. Optimization of AGPAT11 enzymatic activity in cellular lysates. A: AGPAT activity in cell lysates upon processing of the cells either by three cycles of freeze-thaw or by sonication. B: The AGPAT activity when determined either with freshly prepared lysates or frozen and thawed again. C: AGPAT activity obtained from the cellular lysate frozen and used for the enzymatic activity. All data are expressed as mean ± SD from two independent experiments in triplicate. from human cervical cancer, doubled compared with HEK293 cells. In the CRC cell lines HT29, SW480, and CaCo-2, AGPAT11 showed 2-fold, 5-fold, and 3-to 5-fold increased expression, respectively; however, T84 and SW620 cells did not. It is interesting to note that SW620 is derived from SW480 but seems to lose its ability to overexpress AGPAT11. We also examined the expression of AG-PAT11 in pathological tissues. In human cancer tissues, there is a distinct upregulation of AGPAT11 in breast cancer tissue compared with normal breast ( Fig. 7B ). Because in normal breast, AGPAT11 expression is undetectable, it is not possible to present any fold increase in the expression of the AGPAT11 mRNA. The case for cervical cancer is similar ( Fig. 7C ). In CRC tissues, there is at least a 3-to 4-fold increase in the expression of AGPAT11 ( Fig. 7D ). additional acyltransferase activities. It did not show GPAT activity ( Fig. 6B ).

Expression of AGPAT11 in human cancer tissues and cultured cell lines
Because human AGPAT11 has signifi cant homology to human AGPAT9/LPCAT1 that is shown to be upregulated in human colorectal cancer (CRC), we investigated whether the expression of AGPAT11 was also modulated in CRC. We examined the expression of AGPAT11 in cancer cell lines ( Fig. 7A ) compared with HEK293 cell line (which does not represent a cancer cell). The human breast cancer cells MCF-7 and MDAMB231 did not overexpress AGPAT11 compared with the HEK293 cells. The expression of AGPAT11 in HeLa cells, which are derived Bar represents mean ± SD. B: Acyl-CoA specifi city of recombinant human AGPAT11 expressed in AD293 cells. Specifi city of human recombinant AGPAT11 for acyl-CoA donors were determined using sn-1 -oleoyl-LPA as an acceptor and various short-, medium-, and long-chain fatty acyl-CoA as donors. All enzymatic activities were determined in two independent experiments in triplicate. Bar represents mean ± SD.
The human AGPAT11 is located on chromosome 16q.13 and consists of 14 exons (supplementary Table II). When aligned with other known AGPATs , AGPAT11 shows signifi cant homology to AGPAT9/LPCAT1 ( Fig. 1A ) ( 15 ). The human AGPAT11 is highly conserved with the mouse and zebrafi sh ( Fig. 1B ). However, there is no ortholog for this gene to be found in D. melanogaster or C. elegans . Tissue expression patterns, using quantitative RT-PCR analysis, revealed that AGPAT11 is highly expressed in the lung, spleen, and leukocytes and also present in most other tissues. It is least expressed in the heart, liver, and thymus. This tissue expression pattern is also very similar to that of human AGPAT9, reported earlier, except for qualitative differences ( 8 ).
The expression of AGPAT2 is upregulated in ovarian cancer ( 16 ). Patients with ovarian cancer have higher levels of circulating LPA, and the ascites fl uid is enriched in LPA level ( 17 ). Because the human AGPAT9/LPCAT1 is reported to be upregulated in CRC ( 18 ), and with the close homology of this isoform to AGPAT11, we examined the human tumor tissues for the expression of AGPAT11. We looked at the cultured cells as well as those from the tumor tissue. Compared with the normal human breast tissue (with some fi brocystic changes), breast cancer tissue (with 50-100% tumor tissue) showed signifi cantly increased expression of AGPAT11. We also observed upregulation of AGPAT11 in cervical cancer tissue (tumor grade 15-90%). The expression of AGPAT11 was refl ective to the degree of tumor tissue present. The higher the tumor DISCUSSION Our goal has been to identify new isoforms for the AG-PAT enzymes and characterize their tissue expression patterns and enzymatic activities in the hope that one of these isoforms, in addition to AGPAT2, is also highly expressed in the adipose tissue, which might provide additional genetic loci for patients with lipodystrophy. We have earlier reported mutations in the AGPAT2 gene that lead to the loss of adipose tissue in humans ( 6 ). This observation has now been corroborated in Agpat2 null mice ( 14 ).
In this study, we demonstrate that the recombinant AG-PAT11 protein had AGPAT enzymatic activity when expressed in AD293 cells and it localizes to the ER. This enzyme prefers LPA with oleic acid at its sn-1 position as an acyl acceptor as well as oleoyl-CoA as the acyl donor. This substrate specifi city is very similar to AGPAT9 and 10, which we reported earlier ( 8,9 ). We also showed that AGPAT11 lacks enzymatic activity toward other lysophospholipids, such as LPE, LPG, and LPI. However, we did observe reduced but statistically signifi cant acyltransferase enzymatic activity for LPS, which was only 50% of that for LPA. The signifi cance of this substrate specifi city remains unclear from this study. The AGPAT11 has no GPAT activity. Other investigators have shown that this cDNA has LPCAT activity as well ( 10,11 ). Although we could show robust AGPAT activity, the LPCAT activity did not reach statistical signifi cance (data not shown). It remains unclear why we were unable to detect LPCAT activity. Thus, the results of ours and others require additional experiments to verify these discrepancies. required for the activation of downstream target(s) genes for neoplastic cell proliferation and survival. AGPAT9/LP-CAT1 is not upregulated in the human breast and cervical cancer tissues ( 18 ).
With this report, there are now at least 11 isoenzymes possessing AGPAT activity. An obvious question is why so many of these isoforms are present in the genome, all of which localize to ER, except AGPAT3, which also seems to be present in the Golgi apparatus of the cell ( 22 ). It is possible that despite having similar in vitro enzymatic activity, the specifi city is accorded in conjunction with additional factor(s) still undetermined. A possibility also exists that some of these isoforms are expressed in specifi c ER domains providing AGPAT activity in generating specifi c lipid molecules either for localized cellular function or grade, the greater was the expression of AGPAT11. In CRC tissues, the expression was increased for AGPAT11. However, we observed that in normal colon, AGPAT11 is expressed as well, but less than that observed in the tumor tissue. Thus, we show that in breast and cervical cancers, AGPAT11 is activated, because normal breast and cervical tissue do not reveal signifi cant expression of AGPAT11. An overexpression of AGPAT11 in these tumor tissues would indicate an elevated level of phosphatidic acid, which itself is a signaling molecule. PA can activate and amplify Ras signaling, resulting in mitogen-activated protein kinase and PI3K/AKT for survival pathways for neoplastic anchorage-independent survival of tumors (19)(20)(21). It is also important to mention that a specifi c PA species might be generated by the overexpression of AGPAT11, Fig. 7. Expression of AGPAT11 mRNA in cultured tumor cells and human tumor tissues. A: Shown are the quantitative expression of AGPAT11 in cultured cells representing CRC (T84, HT29, SW480, SW620, and CaCo-2), breast cancer (MCF-7 and MDAMB231), and cervical cancer (HeLa). The expression is normalized to 18S housekeeping gene and expressed relative to HEK293 cells. B: Expression of AGPAT11 in normal and cancer tissues from breast. The quantitative PCR values are expressed as an arbitrary unit where 1 represents C t = 40 and 100 represents C t = 1. Arbitrary units were obtained from two independent determinations. Because of undetectable expression in normal breast, the expression data are not normalized to 18S. The lower panel shows the same PCR analyzed on 2% agarose gel stained with ethidium bromide . Lane 1, normal breast tissue with fi brocystic changes; lanes 2-4, breast cancer tissues with varying degrees of tumor. C: Expression of AGPAT11 in normal and cervical cancer tissues from cervix. The quantitative PCR values are expressed as an arbitrary unit where 1 represents C t = 40 and 100 represents C t = 1. Each bar represents the mean C t values from two independent determinations not normalized to 18S because of undetectable levels of AGPAT11 in normal tissues. The lower panel shows agarose gel analyses: lanes 1 and 2, normal cervical tissues; lanes 3-5, the cervical cancer tissues. D: Expression of AGPAT11 in normal and tumor tissues from CRC. In one out of three normal colorectal tissues, the expression of AGPAT11 was undetectable, and in two out of three colorectal cancerous tissues its expression increased compared with normal tissues. The quantitative PCR values are expressed as an arbitrary unit where 1 represents C t = 40 and 100 represents C t = 1. The lower panel shows the agarose gel analyses: lanes 1-3 are from normal and lanes 4-6 are from cancerous tissues. For details on cancer tissues pathology, see supplementary Table III. localized membrane structure. Alternatively, some of these enzymes function in concert with phospholipases to remodel the newly synthesized phospholipids via the Lands cycle ( 3,4 ). It is important to mention in this context that until now, the colocalization of the two enzymes, AGPATs and phospholipases , has not been demonstrated and none of these enzymes has been shown to possess transacylase enzymatic activity.
PA and diacylglycerol, a dephosphorylated product of PA, are precursors for the biosynthesis for various phospholipids and triacylglycerol. It is possible that all actions for these enzymes are within the membrane where they are localized. The phospholipids are integral components of all the cellular membranes, including those of mitochondria, ER, peroxisomes, and plasma membrane. For ER and mitochondrial biogenesis, there is local demand for specifi c phospholipid species. AGPAT isoforms might fulfi ll this location-specifi c role. To understand the functions of various AGPATs , an antibody to each isoform is required to determine their subcellular localization instead of employing GFP-fusion protein. Future experiments shall be directed toward understanding the specifi c role of each of these AGPATs in tissue models to determine specifi c subcellular localization (microdomain) and by developing mouse models by homologous gene deletion to understand their function in whole animals. In this context, it is important to mention that when Agpat2 null mice were generated and analyzed, an unexpected role of monoacylglycerol acyltransferase 1 in the biosynthesis of triglycerides in liver was discovered ( 14 ).