Macrophages Require Constitutive NF-kappa B Activation To Maintain A1 Expression and Mitochondrial Homeostasis

doi:10.1128/MCB.20.23.8855-8865.2000

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Molecular and Cellular Biology, December 2000, p. 8855-8865, Vol. 20, No. 23
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Macrophages Require Constitutive NF- $kappa$ B Activation To Maintain A1 Expression and Mitochondrial Homeostasis

Lisa J. Pagliari,¹^,² Harris Perlman,¹ Hongtao Liu,¹ and Richard M. Pope¹^,^*

Division of Rheumatology, Department of Medicine,¹ and Integrated Graduate Program in the Life Sciences,² Northwestern University Medical School, Chicago, Illinois 60611

Received 29 August 2000/Accepted 5 September 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

NF- $kappa$ B is a critical mediator of macrophage inflammatory responses, but its role in regulating macrophage survival has yetto be elucidated. Here, we demonstrate that constitutive NF- $kappa$ Bactivation is essential for macrophage survival. Blocking theconstitutive activation of NF- $kappa$ B with pyrrolidine dithiocarbamateor expression of I $kappa$ B $alpha$ induced apoptosis in macrophagelike RAW264.7 cells and primary human macrophages. This apoptosis wasindependent of additional death-inducing stimuli, including Fasligation. Suppression of NF- $kappa$ B activation induced a time-dependentloss of mitochondrial transmembrane potential ( $Delta$ $Psi$ _m) and DNA fragmentation.Examination of initiator caspases revealed the cleavage of caspase9 but not caspase 8 or the effector caspase 3. Addition of a generalcaspase inhibitor, z-VAD.fmk, or a specific caspase 9 inhibitorreduced DNA fragmentation but had no effect on $Delta$ $Psi$ _m collapse, indicatingthis event was caspase independent. To determine the pathway leadingto mitochondrial dysfunction, analysis of Bcl-2 family membersestablished that only A1 mRNA levels were reduced prior to $Delta$ $Psi$ _mloss and that ectopic expression of A1 protected against celldeath following inactivation of NF- $kappa$ B. These data suggest thatinhibition of NF- $kappa$ B in macrophages initiates caspase 3-independentapoptosis through reduced A1 expression and mitochondrial dysfunction.Thus, constitutive NF- $kappa$ B activation preserves macrophage viabilityby maintaining A1 expression and mitochondrialhomeostasis.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The mechanism(s) by which the pleiotropic transcription factor nuclear factor kappa B (NF- $kappa$ B) regulates cell survival remainsunclear. Mice null homozygous for the p65 alleles or I $kappa$ B kinase $beta$ are embryonic lethal due to extensive liver cell death (6,40), demonstrating that NF- $kappa$ B p65 or its activating kinase isessential for development. Embryonic macrophages and fibroblastsfrom p65 null mice are susceptible to tumor necrosis factor alpha(TNF- $alpha$ )-induced apoptosis, which is rescued by overexpressionof p65 but not p50 (5). Furthermore, inhibition of NF- $kappa$ B byI $kappa$ B $alpha$ overexpression or by the chemical inhibitor pyrrolidine dithiocarbamate(PDTC) rendered many cell types normally resistant to the effectsof TNF- $alpha$ susceptible to TNF- $alpha$ -induced apoptosis (21, 61, 62).In addition, suppression of NF- $kappa$ B activation has been shown toenhance apoptosis following radiation or treatment with chemotherapeuticagents (59, 64, 66). Although many investigations have employedexogenous mediators to induce apoptosis following NF- $kappa$ B inactivation,few have reported the occurrence of apoptosis in response to NF- $kappa$ Binhibition in the absence of additional stimuli (16, 36, 38,67).

Unlike monocytes, normal macrophages are long-lived cells resistant to many apoptotic stimuli, including Fas and TNF- $alpha$ receptorligation, ionizing radiation, and multiple antineoplastic or cytotoxicagents (32, 33, 49, 52). We recently demonstrated thatexpression of FLICE-inhibitory protein (Flip) protected differentiatedmacrophages from Fas-mediated apoptosis (52); however, the mechanismsresponsible for macrophage survival have not been fully elucidated.In vitro, both monocytes and macrophages display constitutiveactivation of NF- $kappa$ B p50 homodimers; however, p65-p50 heterodimersare present only in differentiated macrophages (13, 22). Hence,the constitutive presence of transcriptionally active p65-p50heterodimers in macrophages may provide resistance to celldeath.

Apoptosis may be initiated through two distinct mechanisms: (i) death receptor (DR) ligation (50, 63) or (ii) direct mitochondrialdamage associated with a loss of mitochondrial transmembrane potential( $Delta$ $Psi$ _m), cytochrome c release, and activation of caspases 9 and3 (34, 45, 70). DR signaling activates caspase 8 (7,46), which can directly cleave caspase 3 and, in certain celltypes, may also induce $Delta$ $Psi$ _m loss through activation of Bid (24).Other members of the Bcl-2 family, including the antiapoptoticproteins Bcl-2, Bcl-x_L, and A1 and the proapoptotic proteins Baxand Bad, have also been implicated in regulating mitochondrialstability (23). Furthermore, both Bcl-x_L and A1 may be regulatedby NF- $kappa$ B (11, 69), suggesting a role for NF- $kappa$ B in regulatingmitochondrialhomeostasis.

In the present study, we have demonstrated that the constitutive activation of NF- $kappa$ B is necessary for the survival of boththe murine macrophagelike cell line RAW 264.7 and human monocyte-derivedmacrophages. Inhibiting NF- $kappa$ B activation induced apoptosis associatedwith a loss of $Delta$ $Psi$ _m and caspase 9 activation. However, activationof caspase 8 was not observed and z-VAD.fmk or neutralizing anti-Fasligand (FasL) antibody did not prevent $Delta$ $Psi$ _m collapse or cell death,indicating that apoptosis induced by NF- $kappa$ B inhibition was notmediated by DR signaling. Moreover, a specific inhibitor of caspase9 significantly reduced DNA fragmentation but not $Delta$ $Psi$ _m loss orcell death. These data suggest that while DNA fragmentation inducedby NF- $kappa$ B inhibition was caspase dependent, loss of $Delta$ $Psi$ _m and celldeath were caspase independent. Furthermore, caspase 3 activationwas not detected by either immunoblot analysis or cleavage ofa DEVD substrate. Analysis of Bcl-2 family molecules revealedthat A1 mRNA levels were reduced after 3 h of NF- $kappa$ B inhibitionand prior to $Delta$ $Psi$ _m loss. Additionally, ectopic expression of A1provided protection from cell death induced by suppression ofNF- $kappa$ B. Our data demonstrate that blocking the constitutive activationof NF- $kappa$ B in macrophages results in caspase 3-independent apoptosismediated by reduced A1 expression and the loss of $Delta$ $Psi$ _m.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Materials. PDTC, trypan blue, LY 294002, and polymyxin B sulfate were obtained from Sigma Chemical Co. (St. Louis, Mo.). RPMI, Dulbecco'smodified Eagle's medium, fetal bovine serum (FBS), phosphate-bufferedsaline (PBS), Opti-MEM, Lipofectamine, L-glutamine, penicillin,and streptomycin were obtained from Gibco (Gaithersburg, Md.).Propidium iodide (PI) was purchased from Roche Molecular Biochemicals(Indianapolis, Ind.), and rhodamine 123 (Rh123) was purchasedfrom Molecular Probes (Eugene, Oreg.). Anti-FasL antibody (C-20)and rabbit immunoglobulin G (IgG) control were purchased fromSanta Cruz Biotechnology (Santa Cruz, Calif.) and Jackson Laboratories(West Grove, Pa.),respectively.

Cell isolation and culture. Buffy coats (Lifesource, Glenview, Ill.) were obtained from healthy donors. Mononuclear cells, isolated by Histopaque (Sigma)gradient centrifugation, were separated by countercurrent centrifugalelutriation (JE-6B; Beckman Coulter, Palo Alto, Calif.) in thepresence of 10 µg of polymyxin B sulfate/ml, as previously described(52). Isolated monocytes were $>=$ 90% pure as determined by morphology,nonspecific esterase staining, and CD-14 (Becton Dickenson, FranklinLakes, N.J.) expression examined by flow cytometry (not shown).Monocytes were allowed to adhere to plates (Costar, Cambridge,Mass.) for 1 h in RPMI and 1 µg of polymyxin B sulfate/ml. Followingadherence, monocytes isolated from human blood were differentiatedin vitro for 7 days in RPMI containing 20% heat-inactivated FBS,1 µg of polymyxin B sulfate/ml, 0.35 mg of L-glutamine/ml, and120 U (each) of penicillin and streptomycin/ml (20% FBS-RPMI)(32). Seven-day differentiated macrophages strongly expressedmaturation markers, including CD71 and the integrin $alpha$ _v $beta$ ₅, whichis necessary for adenoviral infection of macrophages (data notshown and reference 17). RAW 264.7 cells were obtained fromthe American Type Culture Collection (Manassas, Va.) and culturedin Dulbecco's modified Eagle's medium with 10% heat-inactivatedFBS, 0.35 mg of L-glutamine/ml, and 120 U (each) of penicillinand streptomycin/ml.

Adenovirus infection of human macrophages. Seven-day differentiated macrophages were infected for 2 h in serum-free RPMI at various multiplicities of infection (MOI)with replication-defective adenoviruses expressing either $beta$ -galactosidase(Ad $beta$ gal), green fluorescent protein (AdGFP), or mutant "super-repressor"I $kappa$ B $alpha$ (AdI $kappa$ B $alpha$ ) (31). Following infection, 20% FBS-RPMI was addedat a 1:1 ratio (to 10% FBS) for an additional 12 h. The infectedcells were then washed gently with PBS and cultured in 20% FBS-RPMIfor varioustimes.

Electrophoretic mobility shift assay (EMSA). Nuclear extracts were prepared, as previously described (10), from RAW 264.7 cells or primary macrophages incubated withcontrol medium or medium containing 200 µM PDTC for 6 and 24 h.Macrophages infected with various MOI of either AdGFP or AdI $kappa$ B $alpha$ for 6 and 24 h were also analyzed. An oligonucleotide spanningthe $kappa$ B binding sites of human immunodeficiency virus Ig, previouslyshown to detect NF- $kappa$ B binding, was employed (10). ³²P-labeled oligonucleotide was incubated with 5 to 10 µg of nuclearextract for 20 min at room temperature and electrophoresed on5 to 6% polyacrylamide gels. Unlabeled oligonucleotide verifiedthe specificity of the signal. For supershift assays, 1 to 2 µlof monospecific antibodies to p50 or p65 was incubated with thenuclear extract on ice for 30 min before the addition of labeledoligonucleotide (10, 68). An unrelated antibody (to c-Jun)demonstrated the specificity of p65 and p50 antibodybinding.

Promoter activity assay. RAW 264.7 cells (10⁶/well of a six-well plate) were transiently transfected with Lipofectamine (55, 68) for 4 h with 3µg of an NF- $kappa$ B-specific promoter-reporter consisting of threetandem $kappa$ B sites upstream of a luciferase gene (57). After 24h, the cultures were treated with 5 ng of TNF- $alpha$ and increasingconcentrations of PDTC for an additional 12 h. The cells wereharvested, lysed by freeze-thaw, and quantitated for luciferaseactivity with a Monolight luminometer. Promoter activity is presentedas relative light units (RLU) normalized for protein concentration(RLU per microgram ofprotein).

Viability assays. (i) RAW 264.7 cells. Since RAW 264.7 cells proliferate, the percent viability was determined by comparing the number of live, trypan blue-negativecells in experimental cultures with the number in untreated cultures,which was designated 100% viability. Additionally, transient cotransfectionswere employed to determine viability following ectopic gene expression.RAW 264.7 cells (10⁶) were cultured in six-well plates for 24 h and then cotransfectedfor 4 h with 0.6 µg of cytomegalovirus-enhanced GFP (EGFP) expressionplasmid (Clontech, Palo Alto, Calif.) and 2.4 µg of test plasmids(1:5 ratio of GFP to total DNA) using Opti-MEM and Lipofectamine(1:5 ratio of DNA to lipid). Empty vector was used as a control,and the total plasmid concentration was 3 µg of DNA/transfection.Following transfection, the cultures were washed, incubated for24 h, and, where indicated, treated with 200 µM PDTC for an additional24 h. The RAW 264.7 cells were collected, and GFP-expressing cellswere quantified by flow cytometry. This established cell deathassay (52) employs flow cytometric analyses to determine changesin cell viability as indicated by the number of GFP⁺cells.

(ii) Primary macrophages. PI (3 µg/ml) and 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide (MTT) cleavage were employed to assess viabilityin monocyte-derived macrophages. PI was added just prior to analysisby flow cytometry, and the data are presented as the percentageof cell death (PI⁺ cells) in each culture. Objects with minimal light scatter representingcellular debris were excluded. MTT assays were performed as instructedby the supplier (Sigma), and values were calculated relative tocontrolcultures.

Determination of subdiploid DNA content. At various time points, cultures were harvested, fixed in 70% ethylalcohol, and stained with PI (50 µg/ml) as previously described(53). The apoptotic profile was determined by flow cytometryutilizing a Beckman-Coulter EpicsXL flow cytometer and System2 software. The subdiploid DNA peak (<2 N DNA), immediately adjacentto the G₀/G₁ peak (2 N DNA), represents apoptotic cells and wasquantified by histogram analyses. Objects with minimal light scatterrepresenting debris were excluded, as previously described (52),so that quantitation of the subdiploid population would not beinappropriatelyskewed.

Determination of mitochondrial permeability transition. Mitochondrial dysfunction was assessed by utilizing the cationic lipophilic green fluorochrome Rh123 as previously described(43, 52). Disruption of $Delta$ $Psi$ _m is associated with a lack of Rh123retention and a decrease in fluorescence. Cultures were incubatedwith Rh123 (0.1 µg/ml) for 30 min, harvested, and analyzed byflow cytometry. Mean fluorescence was recorded for each sample,and control cultures at each time point were designated 100% fluorescence.For histogram analysis, objects with minimal light scatter representingdebris were gated out. Where indicated, Rh123 samples were washed,fixed in 70% ethylalcohol, and analyzed for subdiploid DNAcontent.

Western blot analysis. Whole-cell extracts were prepared from primary 7-day differentiated macrophages that were treated as indicated. Extracts (25or 30 µg, as noted) were electrophoresed on sodium dodecyl sulfate-polyacrylamidegel electrophoresis (12.5% polyacrylamide) gels and transferredto Immobilon-P membranes (Millipore, Bedford, Mass.) by semidryblotting. The membranes were blocked for 1 h at room temperaturein PBS-0.2% Tween 20-5% nonfat dry milk (PBS-Tween-milk). Themembranes were then incubated overnight at 4°C in PBS-Tween-milkwith various antibodies: mouse anti-caspase 8 (generous gift fromM. E. Peter), rabbit anti-caspase 9 (Calbiochem, San Diego, Calif.),rabbit anti-PKC $delta$ (Santa Cruz), mouse anti-caspase 3 (TransductionLaboratories, Lexington, Ky.), or mouse anti-tubulin (Calbiochem).The membranes were washed in PBS-Tween-milk and incubated withdonkey anti-rabbit or anti-mouse secondary antibody conjugatedto horseradish peroxidase (1:2,000 dilution; Amersham PharmaciaBiotech, Piscataway, N.J.). Visualization of the protein bandswas performed with the Enhanced Chemiluminescence Plus kit asrecommended by the manufacturer (Amersham PharmaciaBiotech).

Caspase activity assay. Seven-day differentiated primary human macrophages (10⁶) were treated with PDTC and harvested at various times. Cell lysateswere incubated with a synthetic fluorogenic caspase 3-like substrate(Ac-DEVD-AFC; Enzyme Systems Products, Livermore, Calif.) for1 h at 37°C. The lysates were prepared as instructed by the manufacturer.Samples were read on a fluorometer at 400-nm excitation and 505-nmemission.

Caspase inhibition assay. RAW 264.7 cells were plated at 5 × 10⁵ in 24-well plates for 24 h and then treated with PDTC and the general caspase inhibitorz-VAD.fmk or the caspase 9 inhibitor z-LEHD.fmk (both 100 µM;Enzyme Systems Products) for an additional 24 h. Mitochondrialtransmembrane potential was assessed with Rh123, and subdiploidDNA analysis was determined by PIstaining.

Reverse transcriptase (RT)-PCR analysis. Total cellular RNA was isolated as previously described (12), and 1 µg of RNA was reverse transcribed with oligo(dT) primersaccording to the manufacturer's specifications (Promega, Madison,Wis.). The PCR was performed with 2 U of Taq polymerase (RocheMolecular Biochemicals) in a total volume of 50 µl. Amplificationwas carried out for 35 cycles (30 s of denaturing at 94°C, 45s of annealing at 50°C, and 90 s of extension at 72°C) in a DNAthermal cycler. As a control, $beta$ -actin was also amplified underthe same conditions. The A1, Bcl-x_L, and Bcl-2 primers employedhave been described previously (18, 26, 54). The amplifiedproducts were analyzed by 1.2 or 2% (A1 only) agarose gel electrophoresisand visualized under UV illumination after being stained withethidiumbromide.

Statistical analysis. Significance was determined by Student's paired ttest.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Constitutive NF- $kappa$ B activity in macrophages is inhibited by PDTC or expression of I $kappa$ B $alpha$ . To document the state of NF- $kappa$ B activation in macrophages, EMSAs were performed on nuclear extracts from the macrophagelikecell line RAW 264.7 and primary human macrophages. Each cell typedisplayed a constitutive activation of NF- $kappa$ B, which was diminishedby treatment with PDTC (200 µM) (Fig. 1A). Supershift analyses,employing monospecific antibodies to p65 and p50 (data not shown),identified p65-p50 heterodimers and p50 homodimers. The abilityof PDTC to inhibit NF- $kappa$ B transcription was examined by transienttransfection of murine macrophagelike RAW 264.7 cells with a luciferasereporter construct containing a promoter of three tandem $kappa$ B sites(57). TNF- $alpha$ -induced NF- $kappa$ B transcriptional activity was inhibitedby PDTC in a dose-dependent fashion (Fig. 1B). Compared to controlcultures, 200 and 300 µM PDTC significantly (P < 0.03) decreasedNF- $kappa$ B activity.

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FIG. 1. Macrophages exhibit constitutive activation of NF- $kappa$ B which is inhibited by PDTC and AdI $kappa$ B $alpha$ . (A) PDTC inhibits constitutive NF- $kappa$ B activation in macrophages. RAW 264.7 cells and primary human macrophages differentiated for 7 days were treated with 200 µM PDTC for 6 and 24 h, as indicated. The cells were harvested, and nuclear extracts were prepared and analyzed by EMSA as described in Materials and Methods. Unlabeled oligonucleotide (Unlab. oligo) was added (+) to the indicated lanes. The locations of the NF- $kappa$ B p65-p50 heterodimers and p50-p50 homodimers are designated by arrows. The results are representative of three experiments. (B) PDTC decreases TNF- $alpha$ -induced NF- $kappa$ B transcriptional activity as measured by luciferase expression. RAW 264.7 cells transiently transfected with a NF- $kappa$ B promoter reporter (3X-WT-Luc) were incubated with the indicated amounts of PDTC for 30 min and then treated with 5 ng of TNF- $alpha$ /ml for an additional 12 h. NF- $kappa$ B promoter activation was determined by measuring luciferase activity, which is expressed as RLU per microgram of protein. The data are presented as the means ± standard errors of duplicate cultures and are representative of three independent experiments. (C) The constitutive activation of NF- $kappa$ B is diminished in primary macrophages infected with AdI $kappa$ B $alpha$ but not in those infected with AdGFP. Seven-day human macrophages were infected with AdI $kappa$ B $alpha$ or control AdGFP at an MOI of 100 for 6 and 24 h, as indicated. The cells were harvested, and nuclear extracts were analyzed by EMSA as described in Materials and Methods. The data are representative of three independent experiments.

A replication-defective adenovirus vector expressing nondegradable, mutant super-repressor I $kappa$ B $alpha$ (AdI $kappa$ B $alpha$ ) (31) was employedto inhibit the constitutive activation of NF- $kappa$ B. While infectionof primary macrophages with the control vector expressing GFP(AdGFP) did not reduce constitutive NF- $kappa$ B activity, infectionwith AdI $kappa$ B $alpha$ diminished the detection of nuclear NF- $kappa$ B by 6 h (Fig.1C). NF- $kappa$ B activation in untreated primary macrophages was notdue to endotoxin contamination, since all reagents employed wereendotoxin free and the cells were isolated and cultured in thepresence of polymyxin B sulfate, as previously described (32,38, 52). These data demonstrate that NF- $kappa$ B was constitutivelyactivated in both RAW 264.7 cells and primary human macrophagesand that treatment with PDTC or AdI $kappa$ B $alpha$ suppressed NF- $kappa$ Bactivity.

Inhibition of NF- $kappa$ B results in RAW 264.7 cell death. To determine the consequences of NF- $kappa$ B inhibition, RAW 264.7 cells were treated with PDTC and assayed for viability by trypanblue exclusion. After 15 h of PDTC treatment, the number of viableRAW 264.7 cells was reduced by 65% ± 13% (P < 0.003) comparedto untreated controls (Fig. 2A). To establish that the resultsobtained with PDTC were due to NF- $kappa$ B inhibition, an I $kappa$ B $alpha$ -expressingvector (pI $kappa$ B $alpha$ ) was cotransfected into RAW 264.7 cells with a plasmidexpressing EGFP (pEGFP). A 67% ± 10% decrease (P < 0.03) in thenumber of GFP⁺ cells was observed at 24 h following transient transfection withpI $kappa$ B $alpha$ compared to the control vector or one expressing wild-typeNF- $kappa$ B p65 (Fig. 2B). These data suggest that NF- $kappa$ B activity isnecessary for the survival of RAW 264.7 cells.

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FIG. 2. Inhibition of NF- $kappa$ B induces cell death of macrophagelike RAW 264.7 cells. (A) PDTC significantly decreases RAW 264.7 cell viability. Cultures were treated with control medium or 200 µM PDTC for 15 h and assessed for viability by trypan blue exclusion. The viability of control cells represents 100%. The mean ± standard error of four separate experiments is shown. (B) Transient expression of I $kappa$ B $alpha$ reduces the viability of RAW 264.7 cells. The cells were cotransfected with plasmids expressing EGFP plus either control vector or a vector expressing I $kappa$ B $alpha$ or wild-type NF- $kappa$ B p65 (WTp65). The cultures were harvested at 24 h and quantitated by flow cytometry. The number of GFP⁺ cells in cultures cotransfected with the control vector represents 100% for each experiment. The mean ± standard error of three experiments is shown. *, P < 0.003 compared to the control vector.

NF- $kappa$ B inhibition in primary macrophages induces apoptotic cell death. Since NF- $kappa$ B inhibition may alter the viability of a proliferating cell line (i.e., RAW 264.7 cells) differently than thatof noncycling primary cells, the effect of NF- $kappa$ B suppression onterminally differentiated human macrophages was investigated.Similar to RAW 264.7 cells, PDTC-treated primary macrophages exhibiteda significant increase in cell death, measured by PI incorporation,at 72 h compared to control cells (Fig. 3A). The loss of viabilitywas due to apoptosis as determined by cell death enzyme-linkedimmunosorbent assay, which measures nucleosome-associated DNAfragments (data not shown), and by analysis of subdiploid DNAcontent (Fig. 3B).

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FIG. 3. Survival of primary human macrophages is significantly reduced due to apoptosis following NF- $kappa$ B inhibition. (A and B) Seven-day differentiated macrophages were treated with control medium or 200 µM PDTC for 72 h and assayed for cell death by incorporation of PI (3 µg/ml) (A) and apoptosis by subdiploid (<2N) DNA analysis (B), as described in Materials and Methods. The results are representative of three independent experiments. *, P < 0.001 compared to control-treated cells. (C) Infection with AdI $kappa$ B $alpha$ , but not AdGFP, decreases macrophage viability in a dose-dependent manner. Macrophages were infected with the indicated MOI of each virus, and viability was determined at 72 h by MTT assay, as described in Materials and Methods. The data are representative of three independent experiments. *, P < 0.02 compared to AdGFP-infected cells. (D) Macrophage infection with AdI $kappa$ B $alpha$ , but not Ad $beta$ gal, induces apoptosis. Cells were infected at an MOI of 100 with each virus for 72 h and then assayed for subdiploid (<N) DNA content. The data are representative of six experiments. *, P < 0.001 compared to Ad $beta$ gal infection. The values are the means ± standard errors of triplicate cultures.

To determine the effect of specific inhibition of NF- $kappa$ B, human macrophages were infected with AdI $kappa$ B $alpha$ , AdGFP, or a replication-defectiveadenovirus vector expressing $beta$ -galactosidase (Ad $beta$ gal). Primarymacrophages infected with AdI $kappa$ B $alpha$ for 72 h displayed a significantdecrease in viability which was initially observed at an MOI of20 and continued in a dose-dependent manner at MOI of 40, 100,and 200 (Fig. 3C). Cultures infected with the AdGFP control remainedviable at all MOI tested, and immunoblot analyses of AdI $kappa$ B $alpha$ -infectedmacrophages confirmed the expression of super-repressor I $kappa$ B $alpha$ (datanot shown). Additionally, primary macrophages displayed significant(P < 0.001) DNA fragmentation at 72 h following AdI $kappa$ B $alpha$ infectionat an MOI of 100 compared to Ad $beta$ gal-infected cultures (Fig. 3D).Macrophage infection at an MOI of 100 with either AdGFP or Ad $beta$ galdemonstrated that >80% of cells were infected (data not shown).Moreover, cell death induced by AdI $kappa$ B $alpha$ expression occurred selectivelyin macrophages, since fibroblasts infected with AdI $kappa$ B $alpha$ at thesame MOI did not undergo apoptosis (data not shown). These datademonstrate that inhibition of the constitutive activation ofNF- $kappa$ B induced apoptosis of both primary macrophages and RAW 264.7cells.

Suppressing NF- $kappa$ B activity induces a loss of $Delta$ $Psi$ _m. To characterize the mechanism of macrophage apoptosis induced by NF- $kappa$ B inhibition, disruption of the $Delta$ $Psi$ _m was examined by Rh123retention over time. PDTC-treated primary macrophages exhibiteda time-dependent loss of $Delta$ $Psi$ _m, as illustrated in Fig. 4A. Comparedto control cells, PDTC reduced the mean fluorescence intensityof Rh123 at 6 h (P < 0.03), and it continued to decrease at 12,24, 48, and 72 h (Fig. 4B). In contrast, DNA fragmentation wasnot significantly induced by PDTC treatment until 24 h (P < 0.02)compared to untreated macrophages (Fig. 4C). Similar to macrophages,PDTC-treated RAW 264.7 cells also demonstrated a loss of $Delta$ $Psi$ _m asearly as 3 h (P < 0.001) after the addition of PDTC, while anincrease in DNA fragmentation was not observed until 6 h (P <0.05) (data not shown). These data suggest that mitochondrialdysfunction may initiate PDTC-induced macrophage apoptosis.

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FIG. 4. PDTC induces $Delta$ $Psi$ _m collapse prior to DNA fragmentation. Primary human macrophages differentiated for 7 days were treated with control medium or 200 µM PDTC for the indicated times. (A) Representative histograms of PDTC-treated macrophages (gray line) losing Rh123 fluorescence over time compared to control cultures (black line). At the indicated times, the cells were incubated with Rh123 (0.1 µg/ml) for 30 min, harvested, and analyzed by flow cytometry. The number of events (y axis) at each Rh123 fluorescence intensity (x axis) is shown. The data are representative of three independent experiments performed in triplicate. (B) Decreased fluorescence, indicative of $Delta$ $Psi$ _m collapse, occurs in a time-dependent manner in PDTC-treated macrophages. The cells were analyzed for Rh123 fluorescence as described for panel A at the indicated times. The mean fluorescence of control cultures at each time point represents 100%. The mean ± standard error of at least three experiments performed in triplicate at each time point is displayed. (C) PDTC induces DNA fragmentation in a time-dependent fashion. At the indicated times, cultures were assessed for subdiploid (<2N) DNA content as described in Materials and Methods. The values are presented as fold increase over control cultures, designated 1, at each time point. The mean ± standard error of at least four experiments performed in triplicate at each time point is displayed. *, P < 0.05 of PDTC-treated cells compared to control-treated cultures.

To determine if the collapse of $Delta$ $Psi$ _m in PDTC-treated macrophages was specifically due to NF- $kappa$ B inhibition, primary macrophageswere infected with AdI $kappa$ B $alpha$ and assessed for $Delta$ $Psi$ _m integrity. AdI $kappa$ B $alpha$ -infectedmacrophages displayed a time-dependent loss of $Delta$ $Psi$ _m (Rh123 decrease[Fig. 5A]) and subsequent increase in cell death (PI increase[Fig. 5A]) compared to Ad $beta$ gal-infected cells. Rh123 retentionwas significantly reduced (P < 0.02) by 12 h in AdI $kappa$ B $alpha$ -infectedcultures and continued to decrease over time (Fig. 5B). Parallelcultures revealed significant (P < 0.02) DNA fragmentation at12 h post-AdI $kappa$ B $alpha$ infection compared to Ad $beta$ gal-infected cells (Fig.5C). Therefore, in contrast to PDTC-treated macrophages, inductionof DNA fragmentation and loss of Rh123 retention were observedconcurrently in AdI $kappa$ B $alpha$ -infected macrophages. The differences betweenthe two methods of inhibiting NF- $kappa$ B may be due to more effectiveinhibition of NF- $kappa$ B by I $kappa$ B $alpha$ (Fig. 1A and C). In addition, theantioxidant effects of PDTC may have delayed DNA fragmentationby reducing reactive oxygen species (48), which have been shownto contribute to caspase-induced DNA degradation (29) and tomacrophage apoptosis (2, 28). Other than the delay, all characteristicsof cell death were comparable with either method of NF- $kappa$ B inhibition.

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FIG. 5. Macrophage infection with AdI $kappa$ B $alpha$ , but not Ad $beta$ gal, induces $Delta$ $Psi$ _m collapse, cell death, and DNA fragmentation in a time-dependent manner. Primary human macrophages differentiated for 7 days were infected with either AdI $kappa$ B $alpha$ or Ad $beta$ gal, and each sample was analyzed for mitochondrial dysfunction, viability, and subdiploid DNA content. (A) AdI $kappa$ B $alpha$ -infected macrophages display a time-dependent loss of $Delta$ $Psi$ _m, assessed by decreased Rh123 fluorescence (x axis), and a subsequent increase in cell death, as determined by incorporation of PI (3 µg/ml; y axis), compared to Ad $beta$ gal-infected control cells. The data represent one of three replicate samples from a representative experiment. (B) AdI $kappa$ B $alpha$ -infected macrophages exhibit reduced Rh123 fluorescence over time compared to those infected with Ad $beta$ gal. At the indicated times, the cells were incubated with Rh123 (0.1 µg/ml) for 30 min, harvested, and analyzed for Rh123 fluorescence by flow cytometry. The mean fluorescence of Ad $beta$ gal cultures at each time point represents 100% fluorescence. (C) Infection with AdI $kappa$ B $alpha$ , but not Ad $beta$ gal, increases DNA fragmentation in a time-dependent fashion. Following Rh123 analysis, cells were fixed in 70% ethanol and assessed for subdiploid (<2N) DNA content. The results are representative of five independent experiments. The values in panels B and C represent the mean ± standard error of triplicate cultures. *, P < 0.001 of the AdI $kappa$ B $alpha$ -infected cells compared to Ad $beta$ gal infection.

To further confirm that inhibiting NF- $kappa$ B activity in macrophages results in $Delta$ $Psi$ _m collapse and apoptosis, two additional methodswere employed to suppress NF- $kappa$ B activation. A proteasome inhibitor(MG132) or a peptide that blocks the NF- $kappa$ B nuclear localizationsignal (SN50), both previously shown to inhibit NF- $kappa$ B activity(42, 56), induced $Delta$ $Psi$ _m loss and apoptosis in a time-dependentmanner (data not shown). Collectively, these data demonstratethat inhibiting constitutively active NF- $kappa$ B in macrophages induced $Delta$ $Psi$ _m collapse andapoptosis.

NF- $kappa$ B inhibition induces caspase 9 activation and macrophage apoptosis independent of DR signaling. Since macrophages express both Fas and FasL on their surfaces (52), the contribution of Fas signaling in NF- $kappa$ B inactivation-inducedapoptosis was investigated. Preincubation with neutralizing anti-FasLantibody did not protect primary macrophages from DNA fragmentation(data not shown) or $Delta$ $Psi$ _m collapse (Fig. 6A), suggesting that themechanism did not involve Fas receptor signaling. Additionally,TNF- $alpha$ , which can be produced by activated macrophages and hasbeen shown to induce apoptosis in the presence of NF- $kappa$ B inhibition(1, 5), was not detected in the culture supernatants ofuntreated or adenovirus-infected macrophages (data not shown).

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FIG. 6. Macrophage apoptosis induced by NF- $kappa$ B inhibition involves caspase 9 activation but is independent of DR signaling and caspase 3 or 8 activation. (A) Blocking Fas-FasL interactions did not prevent PDTC-induced loss of $Delta$ $Psi$ _m. Primary human macrophages differentiated for 7 days were incubated with 10 µg of neutralizing anti-FasL antibody or control IgG/ml for 30 min, followed by the addition of 200 µM PDTC for 24 h. The cells were then incubated with Rh123 (0.1 µg/ml) for 30 min, harvested, and analyzed for Rh123 fluorescence by flow cytometry. The control cultures represent 100% Rh123 fluorescence. The data are presented as the mean ± standard error of triplicate cultures and are representative of two independent experiments. (B) PDTC treatment induces caspase 9 activation without detectable activation of caspase 8 by Western blot analysis. Whole-cell extracts (25 µg) were prepared from 7-day macrophages treated with 200 µM PDTC for the indicated times. Extracts were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis on 12.5% polyacrylamide gels and then transferred to Immobilon P membranes for immunoblot analysis with anti-caspase 8 or anti-caspase 9 antibodies. The proform of caspase 8 is 57 kDa, and the active form of caspase 9 is 19 kDa. Tubulin detection was employed to control for protein loading. (C) PDTC-induced caspase 3 cleavage is not detectable by Western blot analysis. Whole-cell extracts (30 µg) were prepared as described above and probed with anti-caspase 3 antibody. The caspase 3 proform (32 kDa) is shown, and anti-tubulin antibody was utilized to control for protein loading. (D) Caspase 3 activity is not induced in PDTC-treated macrophages as assessed by DEVD cleavage. Seven-day macrophages treated for 24 h with 200 µM PDTC or vehicle control were harvested, lysed, and incubated with Ac-DEVD-AFC at 37°C for 1 h as described in Materials and Methods. Macrophages incubated with 50 µg of LY294002/ml were employed as a positive control for caspase 3 activity. *, P < 0.001 compared to PDTC-treated cells. The mean ± standard error of triplicate cultures is shown. The data are representative of two independent experiments. (E) PKC $delta$ is cleaved following PDTC treatment. Whole-cell extracts (30 µg) were prepared as described above and probed with anti-PKC $delta$ antibody. Cleaved PKC $delta$ (43 kDa) and tubulin, to control for protein loading, are shown. The results in panels B, C, and E are representative of three separate experiments.

To further characterize the mechanism of apoptosis induced by NF- $kappa$ B inhibition, caspase activation was assessed. Seven-daymacrophages were incubated with 200 µM PDTC and assayed for caspase8 and caspase 9 activation at various times. Immunoblot analysesof PDTC-treated macrophages revealed that caspase 8 was not activated,as determined by the stable level of procaspase 8 (Fig. 6B) anda lack of cleaved active caspase 8 (data not shown), suggestingthat DR signals had not been initiated. In contrast, active caspase9 was identified at 12 h of PDTC treatment and was sustained through72 h (Fig. 6B). Surprisingly, caspase 3 activation was not observed.Procaspase 3 levels were unaltered by the addition of 200 µM PDTC(Fig. 6C) or infection with AdI $kappa$ B $alpha$ (data not shown), and cleavedcaspase 3 (not shown) was not detected by employing an antibodypreviously documented by us and others to recognize both the procaspaseand cleaved forms of caspase 3 (30, 52). Furthermore, comparedto control-treated cells, PDTC-treated primary macrophages didnot exhibit increased caspase 3 activity at 24 (Fig. 6D) or 48h (data not shown), as assessed by cleavage of fluorogenic DEVD-containingpeptides. In contrast, treatment with the phosphatidylinositol3-kinase inhibitor LY294002, previously shown to decrease macrophageviability (35), strongly induced caspase 3 activity (Fig. 6D).Despite a lack of caspase 3 activation, cleavage of cellular proteinsindicative of apoptosis, such as PKC $delta$ (Fig. 6E) and PARP (datanot shown), was also observed. Collectively, these data indicatethat inhibiting NF- $kappa$ B resulted in caspase 9 activation and PKC $delta$ cleavage, independent of DR signals or activation of caspase 8or3.

Caspase 9 inhibitors reduce PDTC-induced macrophage apoptosis. To determine if caspase activation is essential for cell death following NF- $kappa$ B inactivation, RAW 264.7 cells were culturedwith either a general caspase inhibitor (z-VAD.fmk) or a specificinhibitor of caspase 9 (z-LEHD.fmk). Treatment with 100 µg ofthe caspase 9 inhibitor or z-VAD.fmk/ml did not prevent PDTC-inducedmitochondrial dysfunction (Fig. 7A), indicating that loss of $Delta$ $Psi$ _moccurred independently of caspase inhibition. These data furthersupport the observation that DR signaling and caspase 8 activationwere not responsible for initiating PDTC-induced $Delta$ $Psi$ _m loss andapoptosis (Fig. 6A and B). In contrast, DNA fragmentation wassignificantly decreased by the addition of either the caspase9 inhibitor (P < 0.004) or z-VAD.fmk (P < 0.02) (Fig. 7B). Furthermore,PDTC-treated RAW 264.7 cells displayed a loss of viability, whichwas not rescued by the addition of these caspase inhibitors (Fig.7C). These data demonstrate that although the caspase 9 inhibitorand z-VAD.fmk provided protection from DNA fragmentation, theydid not prevent $Delta$ $Psi$ _m collapse or cell death. Collectively, thesedata indicate that DNA fragmentation induced by NF- $kappa$ B inhibitionis caspase dependent while mitochondrial dysfunction and subsequentcell death are independent of caspase activation.

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FIG. 7. Caspase inhibition reduces PDTC-induced DNA fragmentation but does not prevent $Delta$ $Psi$ _m collapse or cell death. RAW 264.7 cells were incubated, as indicated, with 100 µg of either a general caspase inhibitor (z-VAD.fmk) or a caspase 9 inhibitor (z-LEHD.fmk)/ml and 200 µM PDTC for 24 h. Analyses of mitochondrial dysfunction, DNA fragmentation, and cell viability were performed on each sample. (A) PDTC-induced loss of $Delta$ $Psi$ _m, determined by decreased Rh123 fluorescence, was not prevented by the presence of either caspase inhibitor. Cultures were incubated with Rh123 (0.1 µg/ml) for 30 min, harvested, and analyzed for Rh123 fluorescence by flow cytometry. Vehicle control cultures were designated 100% fluorescence. (B) Caspase inhibition reduces PDTC-induced DNA fragmentation. Following Rh123 analysis, cells were fixed in 70% ethanol and assessed for subdiploid (<2N) DNA content as described in Materials and Methods. *, P < 0.02 compared to PDTC alone. (C) PDTC-induced cell death, as determined by PI (3 µg/ml) incorporation, was not prevented by caspase inhibition. All values represent the mean ± standard error of triplicate cultures. The results are representative of two independent experiments.

Expression of A1 protects macrophages from apoptosis induced by NF- $kappa$ B inhibition. To elucidate the events leading to mitochondrial dysfunction in NF- $kappa$ B-inactivated macrophages, the expression of Bcl-2 familymembers was assessed. Neither Bcl-2 nor Bcl-x_L was decreased followingthe inhibition of NF- $kappa$ B, as determined by RT-PCR analysis (Fig.8A) or Western blotting (data not shown). In contrast, A1 mRNAwas dramatically reduced in PDTC-treated (Fig. 8A) or AdI $kappa$ B $alpha$ -infected(data not shown) macrophages compared to control macrophages orneutrophils (51). RNase protection assays confirmed that A1expression was diminished following NF- $kappa$ B inhibition (data notshown). Furthermore, the expression of the proapoptotic proteinsBad and Bax was not increased in PDTC-treated macrophages (datanot shown). These data suggest that a reduction in A1 expressionmay be responsible for inducing mitochondrial dysfunction followingNF- $kappa$ B inhibition.

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FIG. 8. A1 protects macrophages from apoptosis induced by NF- $kappa$ B inhibition. (A) A1, but not Bcl-2 or Bcl-x_L, mRNA levels were dramatically reduced following NF- $kappa$ B inhibition. RT-PCR analysis was performed on 7-day macrophages treated with 200 µM PDTC for 0, 3, 6, or 12 h. Granulocyte RNA was employed as a positive control for A1 expression. As a control for quantification, $beta$ -actin was also amplified. (B) Transient expression of A1 prevented PDTC-induced RAW 264.7 cell death. The cells were cotransfected with pEGFP and either pA1 or control vector as described in Materials and Methods. Twenty-four hours after transfection, the indicated cultures were treated with 200 µM PDTC (+PDTC) for an additional 24 h. Viability was determined by the number of GFP⁺ cells. *, P < 0.002 compared to control vector with PDTC. The data are presented as the mean ± standard error of triplicate cultures and are representative of three independent experiments.

If macrophage apoptosis induced by the inhibition of NF- $kappa$ B is dependent on a decrease in A1, restoring A1 expression may beprotective. An expression plasmid encoding A1 (pA1 [69]) wascotransfected with pEGFP into RAW 264.7 cells, which were thentreated with PDTC for 24 h. Compared to those transfected withcontrol vector, cells expressing A1 were significantly (P < 0.002)protected against PDTC-induced cell death (Fig. 8B). No differencewas observed between the untreated control-transfected cells andPDTC-treated cells transfected with A1. These data indicate thatA1 provided protection against cell death induced by NF- $kappa$ Binhibition.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The constitutive activation of NF- $kappa$ B is essential for macrophage viability. The requirement for NF- $kappa$ B activation in the presentstudy was not due to the fact that the primary human macrophageswere terminally differentiated, since inhibition of constitutivelyactivated NF- $kappa$ B in proliferating macrophagelike RAW 264.7 cellsalso induced apoptosis. Previous investigations have focused onthe effect of NF- $kappa$ B inhibition in response to apoptotic stimuli,such as DR ligation, radiation, or chemotherapeutic compounds,in a variety of cell types, including macrophages (5, 59,64, 66). In contrast, our data are novel in that NF- $kappa$ B inhibitionin the absence of additional apoptotic stimuli resulted in macrophageapoptosis, demonstrating that constitutive NF- $kappa$ B activation isessential for macrophagesurvival.

The constitutive activation of NF- $kappa$ B is not essential for the survival of all cells types. In contrast to macrophages, fibroblasts,endothelial cells, and epithelial cells did not undergo apoptosisfollowing NF- $kappa$ B inhibition by PDTC or I $kappa$ B $alpha$ (data not shown andreferences 31, 60, and 66). However, similar to macrophages,other cells of the immune system, including both B and T lymphocytes,exhibited constitutive NF- $kappa$ B activation (36, 47) and underwentapoptosis following NF- $kappa$ B inhibition (3, 36, 67), althoughthe responsible mechanisms have not been wellcharacterized.

Our data provide novel insights into the mechanism by which the constitutive activation of NF- $kappa$ B protects macrophages fromcell death. Here, we show that macrophage apoptosis induced byNF- $kappa$ B inhibition was mediated by a loss of $Delta$ $Psi$ _m, activation ofcaspase 9, and cleavage of cellular proteins and DNA. DR ligationwas not responsible for apoptosis, as caspase 8 was not activatedand z-VAD.fmk did not protect against $Delta$ $Psi$ _m loss. Additionally,TNF- $alpha$ was not detected in the culture supernatants (data not shown),and interruption of Fas-FasL interactions did not protect againstmacrophage apoptosis following NF- $kappa$ B inhibition. This contrastswith previous studies, in which the expression of I $kappa$ B $alpha$ sensitizedcells to $Delta$ $Psi$ _m collapse induced by TNF- $alpha$ and mediated by caspase8 activation (9, 65). Thus, our data document a direct rolefor constitutively activated NF- $kappa$ B in maintaining macrophage viabilityby regulating mitochondrialhomeostasis.

Unexpectedly, macrophage apoptosis induced by suppressing constitutively activated NF- $kappa$ B occurred through a caspase 3-independentpathway. Although caspase 9 activation was documented followingthe initial loss of $Delta$ $Psi$ _m and the caspase 9 inhibitor effectivelyreduced DNA fragmentation, caspase 3 activation was not detectedby either Western blot analysis or functional activity, regardlessof the method employed to inhibit NF- $kappa$ B. These are the first datato document a caspase 3-independent apoptotic pathway in primarymacrophages. Similar to these results, a recent study demonstratedthat inhibition of constitutive NF- $kappa$ B activity in normal, humanT lymphocytes resulted in apoptosis without activation of caspase3 (36). However, the mechanism responsible for apoptosis andthe effect of caspase inhibitors on cell viability were not reported(36). It is possible that access to procaspase 3 was impeded(44) or an inhibitor of caspase 3 was present (14) under theconditions utilized, resulting in a lack of caspase 3 cleavageby activated caspase 9. Perhaps cleaved, proteolytically activePKC $delta$ (20) or another caspase, such as caspase 7 (19), wasresponsible for DNA fragmentation following NF- $kappa$ B suppression.The absence of caspase 3 activation by cleaved caspase 9 may beunique to NF- $kappa$ B inhibition, because macrophage cell death inducedby the phosphatidylinositol 3-kinase inhibitor LY294002 was associatedwith both mitochondrial dysfunction (data not shown) and caspase3 activation (Fig. 6D). Likewise, we have observed caspase 3 activationin monocytes undergoing spontaneous apoptosis mediated by Fas-FasLinteractions (52). Our data indicate that macrophage apoptosisinduced by the inhibition of constitutive NF- $kappa$ B activation wasinitiated by loss of $Delta$ $Psi$ _m and employed a caspase 3-independentpathway for DNAdegradation.

The mechanism by which inhibition of NF- $kappa$ B in macrophages initiates $Delta$ $Psi$ _m collapse was also examined. NF- $kappa$ B inactivation resultedin the marked reduction of A1 expression prior to $Delta$ $Psi$ _m collapse,even though the expression of other Bcl-2 family members was unchanged(Fig. 8A). Previous investigations have documented induced A1expression in macrophages following stimulation (51); however,our findings are novel, since they demonstrate an exquisite sensitivityof A1 regulation to constitutive NF- $kappa$ B activation. Additionally,prior studies have reported that A1 may protect against apoptosisin the presence of NF- $kappa$ B suppression (15, 37, 65, 69).In contrast to our data, however, apoptosis was observed onlyin response to exogenous death-inducing stimuli, such as TNF- $alpha$ and anti-Fas antibody (15, 37, 65, 69). Supporting theimportance of our observations, the ectopic expression of A1 protectedagainst macrophage apoptosis induced by NF- $kappa$ B inhibition. Additionally,A1 expression has been shown to contribute to myeloid differentiation(41), which may be due to protection against apoptosis, consistentwith our observations in macrophages. In contrast to our resultsfor A1, Bcl-x_L, another Bcl-2 family molecule regulated by NF- $kappa$ B(11), was not reduced when constitutive NF- $kappa$ B activation wasblocked. Although the inhibitor of apoptosis proteins (IAPs) mayalso be regulated by NF- $kappa$ B (65), IAPs arrest apoptosis by preventingthe activation of caspases 9 and 3 (14) and therefore are unlikelyto affect apoptosis initiated by a caspase-independent $Delta$ $Psi$ _m collapse(Fig. 7A). Our data provide important insight into the role ofA1, suggesting that it may be an indispensable mitochondrial homeostaticmolecule and mediator of the antiapoptotic function of constitutivelyactivated NF- $kappa$ B inmacrophages.

Although the role of NF- $kappa$ B in macrophage apoptosis has been previously investigated, the results differed from those presentedhere. Macrophages generated in vitro from hematopoietic precursorsof embryonic-lethal p65 knockout (p65^/) mice were not reported to undergo spontaneous apoptosis butwere sensitive to TNF- $alpha$ -induced cell death (5). The precursorsemployed in this study were treated with macrophage growth factorsthat may have activated other transcription factors, includingother NF- $kappa$ B subunits. In hematopoietic lineages, c-Rel and p65may serve redundant functions (25), suggesting that c-Rel activitymay have compensated for the loss of p65. However, the ectopicexpression of the I $kappa$ B $alpha$ employed in the present study, which avidlybinds any NF- $kappa$ B complex containing p65 or c-Rel (4), effectivelyinhibited all species of NF- $kappa$ B detected (Fig. 1C). Another investigationutilizing a degradable form of I $kappa$ B $alpha$ did not observe macrophageapoptosis, even in the presence of TNF- $alpha$ (17). Potential explanationsfor this discrepancy include the culturing of peripheral blood-derivedmonocytes in the presence of macrophage colony-stimulating factor,which may have induced other factors that protected against apoptosis(8), and the use of a degradable form of I $kappa$ B $alpha$ , which, whenunbound, is unstable and rapidly degraded (39, 58). In contrast,our study employed monocytes differentiated in serum alone anda nondegradable, mutant I $kappa$ B $alpha$ that may have been more effectiveat preventing NF- $kappa$ B activation. Our results were validated byutilizing four different methods to suppress NF- $kappa$ B activation,all of which resulted in $Delta$ $Psi$ _m collapse andapoptosis.

In summary, we have shown that the constitutive activation of NF- $kappa$ B is necessary for macrophage survival and that inhibitionof NF- $kappa$ B activity resulted in macrophage apoptosis initiated bya decrease in A1 expression and loss of $Delta$ $Psi$ _m, independent of DRligation. The persistence of macrophages has been implicated inthe pathogenesis of diseases such as rheumatoid arthritis andatherosclerosis. Consistent with our data, nuclear, activatedNF- $kappa$ B was identified in vivo in rheumatoid arthritis synovialtissue macrophages (27), indicating that activated NF- $kappa$ B mayprevent macrophage apoptosis. The data presented here provideimportant insights into the mechanism of macrophage survival andsuggest a potential novel therapeutic approach through the inhibitionof NF- $kappa$ B orA1.

	ACKNOWLEDGMENTS

This work was supported by National Institutes of Health grants N01-AR62221, RO1-AR43642, and P60-AR30692 to Richard M.Pope.

We thank Christian Jobin for kindly providing AdI $kappa$ B $alpha$ and Celine Gelinas for generously providing the A1 plasmid. We also thankKariman Dadbeh and Kathleen Carrigan for their assistance in viruspreparation, as well as Mary Paniaqua for the flow cytometry conductedat the Robert H. Lurie Comprehensive Cancer Center, Flow CytometryCore Facility of the Northwestern University Medical School, Chicago,Ill.

	FOOTNOTES

^* Corresponding author. Mailing address: Division of Rheumatology, Department of Medicine, Northwestern University Medical Schooland the Chicagoland Veterans Administration Medical Center, 303E. Chicago Ave., Ward 3-315, Chicago, IL 60611. Phone: (312) 503-8003.Fax: (312) 503-0994. E-mail: RMP158{at}nwu.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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Macrophages Require Constitutive NF-B Activation To Maintain A1 Expression and Mitochondrial Homeostasis

Macrophages Require Constitutive NF- $kappa$ B Activation To Maintain A1 Expression and Mitochondrial Homeostasis