Abstract
Ornithine decarboxylase (ODC), the first enzyme in polyamine biosynthesis, is highly regulated by many trophic stimuli, and changes in its levels and organization correlate with cytoskeletal changes in normal human epidermal keratinocytes (NHEK). NHEK ODC exhibits a filamentous perinuclear/nuclear localization that becomes more diffuse under conditions that alter actin architecture. We have thus asked whether ODC colocalizes with a component of the NHEK cytoskeleton. Confocal immunofluorescence showed that ODC distribution in NHEK was primarily perinuclear; upon disruption of the actin cytoskeleton with cytochalasin D, ODC distribution was diffuse. The ODC distribution in untreated NHEK overlapped with that of keratin in the perinuclear but not cytoplasmic area; after treatment with cytochalasin D, overlap between staining for ODC and for keratin was extensive. No significant overlap with actin and minimal overlap with tubulin filament systems were observed. Subcellular fractionation by sequential homogenizations and centrifugations of NHEK lysates or detergent and salt extractions of NHEK in situ revealed that ODC protein and activity were detectable in both soluble and insoluble fractions, with mechanical disruption causing additional solubilization of ODC activity (three- to sevenfold above controls). Fractionation and ODC immunoprecipitation from [32P]orthophosphate-labeled NHEK lysates showed that a phosphorylated form of ODC was present in the insoluble fractions. Taken together, these data suggest that two pools of ODC exist in NHEK. The first is the previously described soluble pool, and the second is enriched in phospho-ODC and associated with insoluble cellular material that by immunohistochemistry appears to be organized in conjunction with the keratin cytoskeleton.
INTRODUCTION
Altered cell proliferation results from a complex series of events that include altered transcription of genes involved in cell cycle transit, e.g., proto-oncogenes c-myc, c-fos, and ornithine decarboxylase (ODC) posttranscriptional events (Pawson, 1991), and altered cell shape because of a remodeled cytoskeleton (Li and Deshaies, 1993). We reported previously that agents that altered proliferation of normal human epidermal keratinocytes (NHEK) also caused reorganization of the actin cytoskeleton and of localization of ODC, an enzyme important for cell proliferation, suggesting that cellular architecture might influence ODC activity (Pomidor et al., 1995).
ODC is the first enzyme in the biosynthesis of polyamines, cations important for many cellular processes, including chromatin condensation, and protein synthesis (Marton and Morris, 1987). Polyamines alter actin polymerization rates in vitro (Oriol-Audit et al., 1985), and polyamine starvation results in gross cytoskeletal alterations in yeast and Chinese hamster ovary polyamine auxotrophs (Pohjanpelto et al., 1981; Balasundaram et al., 1991). Furthermore, cytoskeletal disrupters modulate ODC regulation by 12-O-tetradecanoylphorbol-13-acetate (TPA) and nerve growth factor (O’Brien et al., 1976; Lakshmanan, 1979).
ODC overexpression has been shown to cause cellular transformation (Auvinen et al., 1992; Moshier et al., 1993) and hyperphosphorylation of p130CAS, which is involved in cell transformation (Hölttäet al., 1993; Auvinen et al., 1995). Recently, rapid activation of ODC in transformed rat fibroblastic cells has been shown to be associated with phosphorylation of ODC accompanied by membrane localization (Heiskala et al., 1999).
Together, these observations suggest that cell shape changes transduced via the cytoskeleton could regulate ODC and that altered ODC activity could influence actin organization and cell shape. We reported recently that cytoskeletal remodeling changed ODC localization and that suppression of ODC activity led to altered cytoskeletal architecture (Pomidor et al., 1995). This regulated ODC distribution was especially intriguing with respect to ODC’s role in cell transformation, because c-myc (Alexandrova et al., 1995) and p53 (Maxwell et al., 1991) can localize to the tubulin network.
We therefore have asked whether changes in ODC localization and cellular architecture occur concomitantly because ODC associates with a cytoskeletal protein complex. If this were the case, upon subcellular fractionation, ODC distribution would correlate with that of the cytoskeletal component(s). In this report, we present evidence by both double immunofluorescence and subcellular fractionation that there are two pools of ODC protein in NHEK. One of these is extracted with the soluble cellular material; the other fractionates with the insoluble material and, by immunofluorescence, appears to associate with keratin. Furthermore, the insoluble ODC appears to be enriched in the phosphorylated form of ODC and rendered inactive while insoluble. These data suggest how a cell could quickly activate ODC upon mitogenic stimulation.
MATERIALS AND METHODS
Materials
l-[1-14C]Ornithine (40–60 mCi/mmol), [35S]methionine (1000 mCi/mmol), and [32P]orthophosphate (1–60 mCi/mmol) were from DuPont–New England Nuclear (Boston, MA) or Amersham (Arlington Heights, IL) with equivalent results. TPA, cytochalasin D, fluorescein isothiocyanate (FITC)- or tetramethylrhodamine isothiocyanate (TRITC)-conjugated secondary antibodies, rabbit anti-actin, mouse anti-monomeric and polymerized tubulin, and a monoclonal antibody panel to bovine hoof keratin were from Sigma (St. Louis, MO). Rhodamine–phalloidin was from Molecular Probes (Eugene, OR). Polyclonal rabbit antiserum to mouse ODC (cross-immunoreactive with human ODC [Leinonen et al., 1987]) has been characterized previously (Isomaa et al., 1983). Furthermore, we have published previously the equivalence of staining for ODC using this polyclonal antibody with a commercially available monoclonal antibody to murine ODC (Pomidor et al., 1995). The mouse monoclonal antibody to human keratin 14 has also been described previously (LL001 [Sexton et al., 1993]).
Cell Culture
NHEK and human dermal fibroblasts were established from neonatal foreskins as described previously and cultured in keratinocyte growth medium (KGM; BioWhittaker/Clonetics, Walkersville, MD) supplemented with 50 μg/ml bovine pituitary extract or DMEM supplemented with 10% newborn calf serum, respectively (Pomidor et al., 1995). Treatments were initiated in fresh medium containing the agent or vehicle alone (100 ng/ml TPA, ethanol; 5 mM α-difluoromethylornithine [α-DFMO], PBS; 1 μg/ml cytochalasin D, dimethylsulfoxide [DMSO]; vehicle concentration ≤ 0.1% [vol/vol]). All procedures using human “surgical waste” were approved by the Institutional Review Board of Thomas Jefferson University.
In metabolic-labeling experiments, for [35S]methionine labeling, NHEK were incubated in methionine-free KGM for 30 min and then methionine-free KGM containing 100 μCi/ml [35S]methionine for 18 h at 37°C; for [32P]orthophosphate incubations, NHEK were incubated in phosphate-free KGM for 30 min and then phosphate-free KGM containing 100 μCi/ml [32P]orthophosphate for 3 h at 37°C. Incorporated counts in all labeling experiments were determined by trichloroacetic acid precipitation.
P0 HeLa cells (Staugaitis et al., 1990) (kind gift of David Colman, Mt. Sinai School of Medicine, New York, NY) were cultured in DMEM containing 10% newborn calf serum. Expression of P0, a neural adhesion molecule, causes keratin filament organization and was induced by incubation with 0.5 mg/ml sodium butyrate for 24 h.
Immunofluorescent Localization
Fixed and permeabilized NHEK (Pomidor et al., 1995) were incubated with ODC antibody (1:1000), human tubulin antibody (1:1000), or mouse monoclonal keratin-14 antibody LL001 (no dilution) in PBS containing 1% BSA for 30 min at 25°C, incubated with FITC- or TRITC-labeled secondary antibody, mounted using Fluoromount-G (Molecular Probes), and observed with epifluorescence using an Olympus BH-2 microscope or by laser confocal microscopy using the Odyssey Intervision System (Noran Instruments, Middleton, WI).
Labeling of Actin with Rhodamine–Phalloidin
Polymerized actin was stained by incubation with 2 μg/ml rhodamine–phalloidin for 30 min at 37°C (Dejana et al., 1987). When cells were double-stained, they were first incubated with ODC antibody, followed by rhodamine–phalloidin.
Cell Fractionation I
NHEK at ∼60% confluence were lysed by incubation with 10 mM Tris-HCl, pH 7.4, 10 mM NaCl, 1.5 mM MgCl2, 0.3 M sucrose, and 0.5% Triton X-100 (vol/vol), at 4°C for 2 min (Soluble, Triton X-100 fraction), and residual soluble material was removed by rinsing with 10 mM Tris-HCl, pH 7.4, 10 mM NaCl, and 1.5 mM MgCl2, at 4°C for 30 s (Wash) (Lenk et al., 1977). The remaining cellular material was scraped into 10 mM Tris-HCl, pH 7.4, 10 mM NaCl, 1.5 mM MgCl2, 1.0% Tween 20 (vol/vol), and 0.5% sodium deoxycholate (wt/vol; DOC), vortexed 30 s, and microcentrifuged 2 min (supernatant = DOC/Tween 20 fraction). The pellet was resuspended by pipetting in 10 mM Tris-HCl, pH 7.4, 500 mM NaCl, and 50 mM MgCl2, incubated 2 min at 25°C, and microcentrifuged 2 min at room temperature (supernatant = High-Salt fraction). The pellet, containing insoluble material, was resuspended by pipetting in Triton X-100 buffer (Insoluble Pellet). The DOC/Tween 20 and high-salt fractions were diluted approximately eightfold and concentrated in Centricon-30 columns, 5000 × g, at 4°C for 60 min (Amicon, Beverly, MA). Before ODC activity assays, dithiothreitol (DTT) was added to a final concentration of 5 mM. In [32P]orthophosphate-labeled cells, 1 mM sodium orthovanadate was included in buffers to inhibit phosphatases; all fractions were also treated with 1 U RNase and 1 U DNase for 30 min at room temperature to remove 32P-labeled nucleic acids.
Cell Fractionation II
NHEK cultured to ∼60% confluence were trypsinized, lysed by three freeze–thaw cycles in 25 mM Tris-HCl, pH 7.4, 0.1 mM Na2EDTA, and 5 mM DTT (ODC buffer), and centrifuged at 150,000 × g at 4°C for 33 min (supernatant = soluble fraction S0). The pellet (P0) was homogenized by 40 strokes of a Dounce homogenizer (pestle B) in 25 mM Tris-HCl, pH 7.4, 0.1 mM Na2EDTA, and 50 μM DTT with or without 2 mM sodium vanadate, incubated 1 h at 4°C, and centrifuged at 150,000 × g at 4°C for 33 min (supernatant from rehomogenization = S1). The pellet (P1) was resuspended by 40 strokes of a Dounce homogenizer in ODC buffer. Before activity assays, DTT was added to S1 to a final concentration of 5 mM.
Lactate Dehydrogenase (LDH) Activity
LDH activity, a marker of soluble proteins, was measured in all fractions (LDL10 kit; Sigma). Those fractions containing LDH activity were considered to contain soluble proteins.
Protein Concentrations
Protein concentrations were determined for all fractions using the Bio-Rad protein assay kit (Richmond, CA).
Western Blotting
Equal volumes of fractions were boiled 3 min in SDS-sample buffer (66 mM Tris-HCl, 30% glycerol, 1% SDS, 5% β-mercaptoethanol, pH 6.8) and fractionated on a 10% SDS-polyacrylamide/4% stacking gel. Proteins were electrophoretically transferred to nitrocellulose (Schleicher & Schuell, Keene, NH), blocked for 2 h with 5% milk (wt/vol, Carnation, Nestlé USA, Solon, OH) in 10 mM Tris-HCl, pH 8.0, 150 mM NaCl, and 0.05% Tween 20 (vol/vol), and incubated with specific antiserum. After washing in 10 mM Tris-HCl, pH 8.0, 150 mM NaCl, and 0.05% Tween 20 (vol/vol), signal was visualized using alkaline phosphatase activity with 5-bromo-4-chloro-3-indolyl phosphate/nitroblue tetrazolium as substrate (ProtoBlot AP kit; Promega, Madison, WI). Western blotting to detect keratin used the monoclonal antibody panel to bovine hoof keratin.
ODC Activity
ODC activity was measured by the 14CO2-release assay, using a final ornithine concentration of 0.5 mM (Seely and Pegg, 1983). Background 14CO2 release was determined in the presence of the ODC inhibitor α-DFMO (a kind gift of Marion-Merrell Dow Research Institute, Cincinnati, OH) and subtracted from the activity. ODC activity was calculated as nanomoles of CO2 per hour per milligram of protein and expressed as a percentage of control values on the basis of this calculation. The significance of differences between means was determined using the Student’s t test for unpaired data.
ODC Immunoprecipitation and Protein Fractionation
Nonspecific immune complexes were removed by incubation of metabolically labeled NHEK fractions with 4 μl of rabbit preimmune serum in 150 mM NaCl, 5.0 mM EDTA, and 50 mM Tris-HCl, pH 7.4 (immunoprecipitation buffer; volume = 450 μl) for 24 h at 4°C, followed by pelleting with formaldehyde-fixed Staphylococcus aureus cells (0.7% final concentration; Calbiochem, Cambridge, MA). The cleared supernatant was immunoprecipitated with 3 μl of rabbit anti-mouse ODC (Isomaa et al., 1983) for 12 h at 4°C, pelleted with S. aureus cells, and washed three times in immunoprecipitation buffer containing 0.5% NP-40 (vol/vol), 0.1% SDS (wt/vol), and 0.5% DOC (wt/vol). Dried pellets were resuspended in SDS sample buffer and fractionated on a 10% SDS-PAGE gel, and labeled proteins were visualized by autoradiography or a PhosphorImager (Molecular Dynamics, Sunnyvale, CA); band intensities were determined by the ImageQuant program (Molecular Dynamics).
Software for Image Reproduction
All blots and micrographs were reproduced and/or assembled using the Adobe Photoshop and Adobe Illustrator packages (Adobe Systems, San Jose, CA).
RESULTS
To investigate the basis for subcellular ODC distribution in NHEK, a two-pronged approach was chosen: 1) immunofluorescence microscopy to investigate whether ODC colocalized to a cytoskeletal filament system and 2) subcellular fractionation to determine the distribution of ODC protein in NHEK.
Immunofluorescent Localization of ODC
Because ODC localization appeared to change in concert with changes in cytoskeletal architecture (Pomidor et al., 1995), we first asked whether ODC as visualized by immunohistochemistry colocalized with immunofluorescently labeled NHEK actin, tubulin, or keratin filament systems. NHEK double-immunostained for cytoskeletal components and ODC were optically sectioned by laser confocal microscopy on the fluorescein (ODC) and rhodamine (cytoskeletal component) channels, and images from the same section were superimposed (Figure 1). In all fields, ODC had a nuclear/perinuclear localization with faint, filamentous cytoplasmic staining (Figure 1, B, E, and H), except in one cell undergoing mitosis (Figure 1E) that had diffuse staining.
Actin staining was comprised of a thick semicircular band of filaments with radial microspikes, suggesting cell spreading (Figure 1). Superposition of the actin and ODC fields (Figure 1C) showed few areas of overlap (green over red = yellow), suggesting that ODC did not colocalize with the actin microfilament system.
The microtubule network (Figure 1D) consisted of fine filaments radiating throughout the cell as well as a perinuclear band; the mitotic cell had short microtubules. Superposition of the ODC and tubulin images (Figure 1, E and D, respectively) showed minimal overlap in the perinuclear region (Figure 1F, yellow), suggesting that they did not significantly colocalize.
The keratin intermediate filament network (Figure 1G) appeared perinuclear with filaments radiating outward to form a fine meshwork. Superposition of the keratin and ODC images (Figure 1I) showed overlap in the NHEK perinuclear region (bright yellow), with some overlap with the cytoplasmic keratin meshwork (orange-yellow). We also examined the localization of ODC in NHEK that had been grown in 2.2 mM Ca2+, one of the signals that induces NHEK differentiation. In NHEK that expressed K10, a suprabasal keratin, ODC distribution was diffuse (our unpublished results). Thus, it seemed that the best candidate for colocalization of ODC would be the NHEK keratin, specifically K14, network. No significant colocalization with microtubule or actin systems was observed.
We reported previously that the actin polymerization inhibitor cytochalasin D caused a more diffuse ODC distribution (Pomidor et al., 1995). We reasoned that this changed-ODC localization could be caused by a specific cytoskeletal association that reflected the remodeling cytoskeleton. ODC staining in NHEK treated with 1 μg/ml cytochalasin D for 6 h was diffuse and comprised of fine filaments throughout the cell excluding the nucleoli (Figure 2, B, E, and H); the majority of stained actin was in microspikes, cell–cell contacts, or actin bundles (Figure 2A). Superposition (Figure 2C) of actin and ODC fields showed some intense yellow areas caused by superposition of ODC with short actin bundles. Little superposition of ODC was observed with actin filaments or microspikes, consistent with our conclusion that colocalization of ODC with the actin microfilament system is unlikely.
After cytochalasin D treatment, tubulin staining (Figure 2D) consisted of fine intersecting filaments. Superposition (Figure 2F) of tubulin and ODC fields showed some overlap in the nucleus (yellow), with green ODC staining throughout the cell. Thus, overlap between tubulin and ODC is most probably attributable to the diffuse ODC signal.
In cytochalasin D–treated NHEK, the keratin network (Figure 2G) appeared as dense, fine, interwoven filaments. Superposition (Figure 2I) of the ODC and keratin fields showed yellow areas throughout the NHEK; some areas with more intense keratin staining (orange→red) were observed in the cortical regions.
In summary, ODC appeared to colocalize significantly with the cytochalasin D–treated NHEK keratin intermediate filament system. Taken together with the data in Figure 1, these stainings suggested that a subset of ODC colocalized with the keratin intermediate filament system.
ODC Localization in Cells Not Containing Keratin
If the subcellular distribution of ODC not only correlated with but was dependent on a keratin intermediate filament network, then a cell that lacked keratin, such as the fibroblast, would show a markedly different ODC organization. We therefore compared ODC staining in human dermal fibroblasts and in NHEK. In contrast to the nuclear/perinuclear staining seen in NHEK (Figure 3A), ODC staining was diffuse throughout the human dermal fibroblasts, excluding the nucleoli (Figure 3B). Therefore, the presence of the keratin filament system correlated with a nuclear/perinuclear localization for ODC.
ODC Localization in P0 HeLa Cells
Finally, we reasoned that if we could induce the keratin filament system to remodel, then ODC should concomitantly relocalize. We therefore examined a stably transfected line of HeLa cells that can be induced by butyrate to express the neural adhesion molecule P0 (Staugaitis et al., 1990); P0 expression causes keratin filament organization. Double immunolabeling showed that untreated P0 cells that express little P0 are small with little apparent keratin organization (Figure 4A) and have diffuse ODC staining (Figure 4B). After butyrate treatment, P0 expression is increased (Staugaitis et al., 1990); the cells become larger and display a keratin filament network with strong perinuclear staining (Figure 4C), while ODC staining (Figure 4D) is filamentous with some distinct perinuclear localization. These observations further support a dependence of ODC localization on keratin intermediate filament organization.
Subcellular Fractionation of NHEK by Detergent and Salt Extractions
The apparent colocalization of ODC with the keratin filament network suggests that some ODC activity should be associated with NHEK subcellular fractions containing insoluble proteins that include keratin. Previously, ODC activity was found only with soluble proteins (Seely et al., 1982; Isomaa et al., 1983), and recently a small percentage has been found to be localized to the plasma membrane after treatment with TPA (Heiskala et al., 1999). Using a subcellular fractionation procedure (Lenk et al., 1977) that solubilizes cellular proteins by detergent and salt extractions, we asked in what fractions ODC activity was measurable. Briefly, soluble proteins were collected in 0.5% Triton X-100 and a wash, membrane proteins and protein–protein complexes were solubilized in 1% Tween 20 and 0.5% DOC, additional protein–protein complexes were disrupted with 500 mM NaCl, and the remaining material that was enriched in keratin was considered insoluble (Lenk et al., 1977). Analysis of equal volumes of each fraction showed that LDH activity, a soluble protein marker, was measurable solely in the Triton X-100 (Soluble) and wash fractions (Figure 5); therefore further detergent and salt treatments extracted proteins considered insoluble. ODC activity was detected in the soluble (Figure 5, histogram, Triton X-100 [Soluble] and Wash) and insoluble (Figure 5, histogram, Doc/T-20 and Ins Pellet) fractions. Therefore, soluble and insoluble pools of ODC activity were detected by subcellular fractionation.
We next asked, using this fractionation scheme, with what fractions did cytoskeletal components and a nuclear protein, pur α (Chang et al., 1996), elute. Pur α was measured because we observed ODC in the nucleus in many micrographs; therefore, “insoluble” ODC activity could be caused by delayed lysis of the keratinocyte nucleus. Western blots showed that both actin and tubulin were extracted in the soluble fractions; keratins were present both in the soluble and insoluble pellet fractions (Figure 6). The nuclear protein pur α was present solely in the soluble fraction (Figure 6); in parallel, DNA was measured predominantly in the soluble fractions with small amounts in the insoluble pellet (our unpublished results). Taken together with the ODC activity measurements, the fractionation profiles indicated that in cellular fractions depleted of actin, tubulin, and nuclear proteins, significant ODC activity was present, suggesting that insoluble ODC activity was associated with insoluble proteins.
Immunoprecipitation of ODC from Subcellular Fractions
We and others have reported previously that TPA treatment causes decreased ODC levels in proliferating NHEK (Fischer et al., 1993; Ruhl et al., 1994). The subcellular distribution of ODC protein was therefore also determined by immunoprecipitation from fractionated, [35S]methionine-labeled NHEK lysate that had been treated with or without TPA (Figure 7A). The immunoprecipitate from equal volumes of each fraction was fractionated by SDS-PAGE, and relative ODC levels were determined by fluorography. A band at the size of ODC was seen in all lanes at varying intensities (Figure 7A, arrow), and TPA treatment caused decreased ODC levels in all bands examined. The identity of the band at 52 kDa as ODC was confirmed by immunocompetition with bacterially expressed mouse ODC (kind gift of T. G. O’Brien, Lankenau Medical Center, Wynnewood, PA, or of L. Persson, University of Lund, Lund, Sweden) (our unpublished result).
Detection of Phospho-ODC
Ornithine decarboxylase has been reported to be phosphorylated on multiple sites (Rosenberg-Hasson et al., 1991; Reddy et al., 1996; Heiskala et al., 1999). We therefore asked 1) where phosphorylated ODC partitioned in this subcellular fractionation scheme and 2) whether our previous observations on the effects of TPA on ODC levels in NHEK were reflected in changes in the levels of phosphorylated ODC because TPA activates protein kinase C. NHEK were treated with or without 100 ng/ml TPA for 6 h while being labeled with [32P]orthophosphate (Figure 7B). Cells were fractionated; equal counts from each fraction were immunoprecipitated with ODC antibody, fractionated by SDS-PAGE, and visualized by autoradiography (Figure 7B). Three immunoprecipitated phosphoproteins were observed only in the Insoluble Pellet fraction, and all showed decreased phosphorylation after TPA treatment. The lowest protein band was of the size for ODC (∼52,000 daltons), and the larger doublet was for phosphorylated keratin (confirmed by Western blotting; our unpublished results).
We then asked whether the keratin bands in the ODC immunoprecipitate resulted from a specific association of ODC with a keratin-containing protein complex. Keratin is primarily insoluble and can be pelleted by ultracentrifugation (Franke et al., 1981). If association between ODC and keratin was specific, then pelleting of keratin would result in pelleting of ODC; if nonspecific, then the majority of ODC should remain in the supernatant. Therefore, lysates from each fraction were clarified by ultracentrifugation at 150,000 × g for 33 min, and the resultant supernatants were analyzed by ODC immunoprecipitation (Figure 7C). No immunoprecipitated phosphoproteins were visible by autoradiography in any lane (Figure 7C, Clarified homogenate panel). The lysate still contained 32P-labeled proteins (Figure 7C, Pellet), indicating that 32P-labeling had not been compromised. This pelleting of ODC was consistent with association of ODC with a keratin protein complex as had been suggested by the coimmunoprecipitation of ODC and keratin.
In summary, ODC protein could be detected in all subcellular fractions, with phosphorylated ODC detected only in the insoluble pellet. Therefore, it appeared that ODC was present as both a soluble and an insoluble protein, with the insoluble pool enriched in phospho-ODC.
Fractionation of NHEK Lysate by Sequential Centrifugation
During purification of ODC, it was reported to be a soluble protein (Seely et al., 1982; Isomaa et al., 1983), with the results we obtained above both confirming and extending this observation. To determine how the pools of ODC activity that we had described above compared with the results in the literature, we next examined the distribution of ODC using a procedure that mimics the first steps in the purification of the enzyme (Isomaa et al., 1983). First, we examined the distribution of ODC activity in the supernatant and pellet of cells that had been lysed by three freeze–thaw cycles followed by ultracentrifugation. This measurement was performed to compare specifically the standard way of measuring ODC activity with the results obtained in the fractionation procedure described above. Furthermore, we asked whether resuspension of the 100,000 × g pellet in 2 mM orthovanadate and ODC buffer would alter ODC activity (Figure 8A), because we had noted that inclusion of the phosphatase inhibitor orthovanadate in the extraction buffers sometimes resulted in increased ODC activities. The ODC activity of the soluble fraction (S0) was many times greater than that of the pellet (P0), consistent with results reported by others for ODC purification (Isomaa et al., 1983). LDH activity was measured and confirmed the assignment of the soluble and insoluble fractions (our unpublished results).
During the first fractionation procedure, cellular proteins that were not yet solubilized remained on the tissue culture plate (our unpublished results) or were pelleted in the later fractionation steps. Therefore, if a protein was interacting with ODC and causing reduced ODC activity, on the basis of the first subcellular fractionation scheme, we would expect this protein to have a solubility different from that of ODC. Therefore, cell lysates were separated (Figure 8, flow chart at top) into a supernatant (S0) and pellet (P0). The P0 pellet was rehomogenized and centrifuged to yield an additional supernatant (S1) and pellet (P1). ODC activity was measured in all fractions and corrected for non-ODC decarboxylations by incubation with α-DFMO. Also, because activation of an ODC isozyme by GTP was reported (Hietala et al., 1988), we asked whether insoluble ODC activity was sensitive to GTP. Whereas the P0 pellet showed little activity, the S1 supernatant showed three- to sevenfold greater specific activity, depending on the treatment, than did the S0 supernatant (Figure 8B). In addition, in untreated samples, the separation into S1 and P1 resulted in significantly greater ODC activity in P1, suggesting that additional ODC was released by resuspension of the P1 pellet (Figure 8B). In parallel, LDH activity measurements in select fractions confirmed that soluble proteins were primarily concentrated in the S0 supernatant, with little LDH activity measured in P0, S1, or P1 (Figure 8B). These experiments suggested that, in addition to the ODC activity associated with soluble proteins, additional ODC was pelleted by centrifugation. The pool that associated with the insoluble fraction could be solubilized by homogenization, and treatments with neither vanadate nor GTP enhanced this effect, suggesting it was solely dependent on the repeated separations. Furthermore, because we measured much lower levels of ODC activity in P0 than in S1 and P1, it suggested that the additional homogenization was somehow activating ODC or that the separation of the proteins into these fractions was necessary for the detection of the additional activity.
Finally, we tested the subcellular distribution of ODC in fibroblasts that had showed no distinct subcellular localization of ODC by immunohistochemistry. This experiment was a means of testing the correlation between the organization of the ODC as observed by immunohistochemistry and the distribution as tested biochemically. We fractionated (see Figure 8, flow chart at top) fibroblasts and measured ODC activities in S0, P0, S1, and P1 (Figure 8C). The P0 pellet had ∼25% of the activity of the S0 supernatant; further homogenization and separation into S1 and P1 did not result in additional ODC activity above that in P0. Again, the majority of LDH activity was found in the S0 fractions, with 6-to 10-fold less activity in P0, S1, and P1, confirming that soluble proteins were released into S0. Taken together, the data presented in Figure 8 identify a pool of ODC that is inactive in NHEK until further homogenization; this pool of ODC is not measured in fibroblasts, consistent with a dependence on proteins not shared between NHEK and fibroblasts, e.g., keratin.
Immunoprecipitation of ODC from Subcellular Fractions Obtained by Sequential Homogenizations and Centrifugations
The level of ODC activity measured in S1 was high, suggesting that significant ODC protein levels should be present in S1 and P1. This was tested by immunoprecipitating ODC protein from the different fractions outlined in Figure 8. Equal counts of metabolically labeled ODC from each fraction were immunoprecipitated, fractionated by SDS-PAGE, and visualized by fluorography, and in parallel, actin, tubulin, and keratin were determined by Western blotting of unlabeled fractions. Figure 9 shows that a radiolabeled protein of the appropriate size for ODC was immunoprecipitated by the ODC antibody in all fractions. Actin was found in all fractions, tubulin was only in S0, and keratin was only in P1. The presence of ODC protein in each fraction supported the interpretation of the ODC activity measurements described in Figure 8.
DISCUSSION
Changes in cell shape are often causally linked to cell proliferation or differentiation via signals transduced through the cell surface (Schaller and Parsons, 1994). Many studies of the molecular mechanisms of proliferation have focused on the regulation of proteins necessary for cell cycle transit, such as myc, fos, p53, and cdc kinases, and altered cytoskeletal architecture to integrate ultimately signal transduction pathways with cytoskeletal changes (Pawson, 1991; Ingber et al., 1995; Assoian and Zhu, 1997). In this article, we have focused on the subcellular distribution of the growth-regulatory enzyme ODC as visualized by immunohistochemistry and as measured in subcellular fractions. We have shown that its subcellular localization appears to depend on the NHEK keratin intermediate filament network and that the pool of ODC that is extracted with the insoluble material is more highly phosphorylated and shows attenuated activity levels until further fractionated from this insoluble material.
Several of the characteristics of NHEK made them ideal for this study. For example, NHEK proliferation and differentiation are profoundly affected by changes in cell shape (Watt et al., 1988; Adams and Watt, 1989), with signals that cause cytoskeletal remodeling also influencing adherence and migration, processes central to wound healing and skin development (Kubler et al., 1991; Watt et al., 1993). We showed previously that TPA treatment changes NHEK cytoskeletal organization and ODC subcellular localization. Interestingly, ODC subcellular localization appeared to be coordinately regulated with actin cytoskeletal organization because cytochalasin D, an actin polymerization inhibitor, and the ODC inhibitor α-DFMO caused a remodeling of the actin cytoskeleton and a concomitant relocalization of ODC (Pomidor et al., 1995). Also, cytochalasin D and the microtubule depolymerizer colchicine abrogate induction of ODC (O’Brien et al., 1976; Lakshmanan, 1979). Finally, a membrane localization for a pool of ODC has been associated with treatment of rat fibroblastic cells with TPA (Heiskala et al., 1999). These studies taken together demonstrate that agents that change ODC localization also regulate ODC activity levels, suggesting a functional role for ODC localization.
In this study, we asked whether the observed coregulation of actin and ODC organization is caused by colocalization of ODC with a cytoskeletal component and investigated the biochemical basis for this phenomenon. We first examined by double immunofluorescence whether ODC colocalized with the actin, tubulin, or keratin filament networks in control and cytochalasin D–treated NHEK. Because cytochalasin D causes all NHEK cytoskeletal systems to remodel, we reasoned that if colocalization is specific, it should occur with cytoskeletal networks in both control and cytochalasin D–treated NHEK. We found that ODC appeared to colocalize to a limited extent with the keratin network in control NHEK and more extensively with this network in cytochalasin D–treated NHEK; colocalization with tubulin or actin was not significant. Furthermore, fibroblasts, which do not have a keratin intermediate filament system, did not appear to organize ODC in the perinuclear/nuclear space. Finally, HeLa cells, which are of epithelial origin, have been shown to organize their keratin intermediate filament system in response to P0 expression (Staugaitis et al., 1990). If ODC localization was dependent on an organized keratin intermediate filament system, then induction of P0 in HeLa cells that are stable clones for this expression would cause ODC to take on a perinuclear subcellular localization. This relationship between an organized keratin intermediate filament system and ODC localization was observed using the P0 HeLa cells.
The apparent colocalization of ODC with the keratin filament network asks the question why epithelial cells have two pools of ODC. Levels of active ODC in NHEK are ∼10–100 times higher than that in fibroblasts (Ruhl et al., 1994), and polyamine levels are similarly elevated (Hickok and Uitto, 1992). In addition, in the ODC-rich, testosterone-stimulated murine kidney, predominant expression of the ODC gene is in the epithelial cells of the proximal tubule (Jänne et al., 1990). These observations suggest that epithelial cells may normally maintain high ODC levels, presumably to generate high polyamine levels. The latter may be important for maintaining differentiated functions; e.g., in NHEK, polyamines can be used in protein cross-linking to form the keratinocyte cornified envelope (Piacentini et al., 1991). We suggest that colocalization of ODC with the cytoskeleton could serve to “buffer” the amounts of soluble ODC in the cell.
If epithelial cells buffer levels of soluble ODC by reversibly immobilizing a pool of ODC to cytoskeletal complexes, we would expect to identify a pool of ODC in NHEK that was extractable with the insoluble material. The distribution of ODC in keratin-containing cells was consistent with this model, with a pool of active ODC in soluble and insoluble protein fractions, as determined by two fractionation procedures. In addition, the amounts of active ODC that could be measured in the insoluble fractions could be greatly increased by mechanical disruption. Finally, fibroblasts that showed no evidence of a distinct subcellular localization for ODC also did not exhibit a similar partitioning of ODC between soluble and insoluble fractions. These observations are consistent with the idea that the pool of ODC that fractionates with the insoluble materials is associated with NHEK-specific proteins, e.g., keratin. It should be noted that these findings are different from and we suspect complementary to those described by Heiskala et al. (1999). They reported a membrane localization for ODC in fibroblasts that had been treated with TPA, and we have observed a similar localization for ODC in NHEK treated with TPA as noted in Pomidor et al. (1995). The possibility of membrane localization was questioned early in our studies. However, on the basis of results with Fractionation Procedure I (Lenk et al., 1977) in which membrane proteins should be extracted in the Triton X-100 or in the Tween 20 and DOC fractions, we thought it unlikely that a membrane localization could explain the staining and the fractionation profiles that we observed. On the basis of the data published by Heiskala et al. (1999), the percentage of ODC localized to the membrane in their system appears to be smaller than the pool cofractionating with the NHEK-insoluble cellular material. Furthermore, Heiskala et al. (1999) have suggested that their subset of membrane-associated ODC may in fact be on the actin cytoskeleton. We cannot rule out that an additional small pool of ODC was solubilized when actin was extracted from the cells. However, our data strongly suggest that the majority of the ODC that is measured in the insoluble fractions copartitions with keratin and associated insoluble proteins.
In rat fibroblastic cells, localization of ODC to the plasma membrane after stimulation by TPA appeared to be mediated by a “phox”-like phosphorylation site present in the ODC protein; the presence of this sequence appears to be necessary for cellular transformation (Heiskala et al., 1999). ODC has many additional phosphorylation sites with serine-303 the major site phosphorylated in vitro with casein kinase II and in COS-1 cells transfected with ODC expression plasmids (Rosenberg-Hasson et al., 1991). Phospho-ODC has been purified from RAW264-transformed macrophages using high-salt elution (200 mM NaCl) (Reddy et al., 1996). Although the subset of ODC that was extracted from the insoluble cellular material was enriched in the phosphorylated form of ODC, no clear function for the phosphorylation could be assigned. In unpublished experiments, we have attempted to dephosphorylate the insoluble material by treatment with alkaline phosphatase to determine whether ODC is readily extracted from this insoluble fraction. Although some of the time additional ODC activity is measured after dephosphorylation, the results are unpredictable and suggest that regulation of localization is likely to be complex and dependent on more than the phosphorylation state of ODC (our unpublished results).
Finally, what is the physiological significance of localizing a pool of ODC with the cytoskeleton, thus allowing ODC protein levels to remain high? Data from transgenic mice suggest that the effects of ODC overexpression are dependent on the cell type. When the human ODC gene was overexpressed in transgenic mice using an ubiquitous promoter, the mice had notable abnormalities in reproduction and brain function (Halmekytöet al., 1991; Halonen et al., 1993). In contrast, when liver expression was targeted, no significant phenotypic changes were observed, probably because of stringent control of liver polyamine levels (Alhonen et al., 1996). Overexpression of the murine ODC gene under control of the keratin 6 promoter in transgenic mice specifically targeting ODC expression to hair follicle stem cells resulted in an increased frequency of papilloma formation (Megosh et al., 1995; O’Brien et al., 1997). In Balb/MK keratinocytes, ODC overexpression also caused increased activation and nuclear translocation of protein kinase CK2, a serine/threonine protein kinase that may be oncogenic (Shore et al., 1997; Xu et al., 1999). Thus, maintaining ODC at high levels in skin could have especially profound effects on tumor formation.
It is intriguing that, in beginning to elucidate the pathway through which ODC overexpression results in cellular transformation, Hölttä, Andersson, and their groups have found that hyperphosphorylation of p130CAS, a src substrate localized to the focal adhesion complex, is a downstream consequence of ODC overexpression (Auvinen et al., 1995) and that transformation is dependent on an intact phox sequence in the ODC (Heiskala et al., 1999). Because the focal adhesion directly tethers actin stress filaments, regulates actin organization, and is an important step in signal transduction cascades (Schaller and Parsons, 1994), it will be of special interest to determine how the changes in cytoskeletal organization that we have observed concomitant with regulation of ODC levels integrate with altered activity of the focal adhesion complex to regulate cell growth and cell adhesion.
ACKNOWLEDGMENTS
The authors thank Yingjie Song and Dr. Alain Mauviel (Thomas Jefferson University) for NHEK cultures, Dr. David Colman (Mt. Sinai School of Medicine) for P0 cells, Dr. Kamel Khalili (Allegheny University of the Health Sciences) for the pur α antibody, Dr. Tom O’Brien (Lankenau Medical Center) for MBP-ODC, and Dr. Lo Persson (University of Lund) for His-ODC. This work was supported by National Institutes of Health grants AR-40022 (N.J.H.), AR-41757 (N.J.H.), and CA-71602 (R.S.T. and N.J.H.) and by grants (O.A.J.) from the Medical Research Council (Academy of Finland), the Finnish Foundation for Cancer Research, and the University of Helsinki. M.M.P. was supported in part by a Smith Fellowship from Thomas Jefferson University.
Abbreviations used:
- α-DFMO
α-difluoromethylornithine
- DMSO
dimethylsulfoxide
- DOC
sodium deoxycholate
- DTT
dithiothreitol
- FITC
fluorescein isothiocyanate
- KGM
keratinocyte growth medium
- LDH
lactate dehydrogenase
- NHEK
normal human epidermal keratinocytes
- ODC
ornithine decarboxylase
- P0
initial pellet after lysis and ultracentrifugation
- P1
pellet resulting from homogenization of the P0 pellet followed by ultracentrifugation
- S0
initial supernatant after lysis and ultracentrifugation
- S1
supernatant resulting from rehomogenization of the P0 pellet and ultracentrifugation
- TPA
12-O-tetradecanoylphorbol-13-acetate
- TRITC
tetramethylrhodamine isothiocyanate
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