A Critical Role of the p75 Tumor Necrosis Factor Receptor (p75TNF-R) in Organ Inflammation Independent of  TNF, Lymphotoxin alpha , or the p55TNF-R

doi:10.1084/jem.188.7.1343

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J. Exp. Med., Volume 188, Number 7, October 5, 1998 1343-1352

A Critical Role of the p75 Tumor Necrosis Factor Receptor (p75TNF-R) in Organ Inflammation Independent of TNF, Lymphotoxin $alpha$ , or the p55TNF-R

By Eleni Douni and George Kollias

From the Department of Molecular Genetics, Hellenic Pasteur Institute, 115 21 Athens, Hellas

Abstract

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Despite overwhelming evidence that enhanced production of the p75 tumor necrosis factor receptor (p75TNF-R) accompanies developmentof specific human inflammatory pathologies such as multi-organfailure during sepsis, inflammatory liver disease, pancreatitis,respiratory distress syndrome, or AIDS, the function of this receptorremains poorly defined in vivo. We show here that at levels relevantto human disease, production of the human p75TNF-R in transgenicmice results in a severe inflammatory syndrome involving mainlythe pancreas, liver, kidney, and lung, and characterized by constitutivelyincreased NF- $kappa$ B activity in the peripheral blood mononuclear cellcompartment. This process is shown to evolve independently ofthe presence of TNF, lymphotoxin $alpha$ , or the p55TNF-R, althoughcoexpression of a human TNF transgene accelerated pathology. Theseresults establish an independent role for enhanced p75TNF-R productionin the pathogenesis of inflammatory disease and implicate thedirect involvement of this receptor in a wide range of human inflammatorypathologies.

Key words: transgenic model; sepsis; ligand-independent signaling; NF- $kappa$ B activation

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

Tumor necrosis factor (TNF) is considered to be a potent proinflammatory molecule involved in the pathogenesis of chroniclocal or systemic inflammation in vivo (1). The effects ofTNF are signaled via two cell surface receptors (TNF-R), designatedp55 and p75TNF-R, which are capable of mediating, either in cooperationor independently, a wide spectrum of cellular responses rangingfrom direct cytotoxicity or apoptosis to cellular proliferationand differentiation (2, 3). Soluble forms of the two TNF-Rs(sTNF-R), which represent the extracellular portions of membrane-associatedTNF-Rs and are shed from them by proteolytic partition, have beenidentified in serum and urine (4, 5). Using TNF or TNF-Rknockout mice it has recently been demonstrated that the TNF/p55TNF-Rpair is essential for many physiological processes such as lymphoidorgan architecture (6, 7), immune cell activation and trafficking(8), and host defence against bacterial (6, 9, 10)or viral infections (11). Moreover, a dominant role of the p55TNF-Ris also apparent in several TNF-mediated pathologies, includingendotoxemic shock in the presence of TNF-sensitizing agents (9,10), or in disease models where constitutively produced (12)or acutely administered levels of TNF are pathogenic (17). Incontrast, using similar assay systems, there has been very littleevidence for a specific role for the p75TNF-R in delivering TNF-dependentsignals in vivo (2, 18). This may reflect either a well-documentedpreference of the p75TNF-R to signal upon binding to transmembrane(19) rather than soluble TNF (20), or an apparently essentialrequirement for this receptor to reach an induced density statein order to transmit an independent biological signal (21, 22).Indeed, a most important feature of the p75TNF-R, which distinguishesit from the p55TNF-R, has been its highly inducible productionmainly on cells of hematopoietic origin (2, 23). Notably,chronic enhanced production of the soluble p75TNF-R demarcatesmany fatal human inflammatory and autoimmune conditions, includingsepsis (24), chronic viral hepatic disease (25), acute respiratorydistress syndrome (26), acute pancreatitis (27), lupus (28),rheumatoid arthritis (29), and AIDS (30). Perhaps most importantly,sustained production of the p75TNF-R during disease is rarelyaccompanied by chronically elevated levels of TNF indicating aregulatory and functional disengagement from TNF (31). However,an independent role for this receptor in the pathogenesis of inflammatorydisease has never been suggested.

To assess the independent in vivo activities of the p75TNF-R we have generated and studied transgenic mice expressing constitutivelyenhanced, yet disease relevant levels of a wild-type human p75TNF-R.Our studies demonstrate that this receptor is capable of inducinga severe multi-organ inflammatory syndrome, affecting mainly theliver, pancreas, kidney, and lung. Similarly to the prolongedNF- $kappa$ B activation observed in PBMC from human septic patients andshown to cause pathology in models of endotoxemia (32), NF- $kappa$ Bbinding activity is found constitutively increased in PBMC fromhup75TNF-R transgenic mice suggesting an in vivo role for thep75TNF-R in triggering this pathogenic cascade. Interestingly,the severity of pathology developing in the human p75TNF-R transgenicmice was analogous to the levels of soluble p75TNF-R measuredin the sera of these animals, simulating the quantitative correlationbetween levels of human soluble p75TNF-R production and severityof human disease (33). Remarkably, the pathogenic potentialof this receptor is shown here to be exerted even in the absenceof its known ligands, TNF or lymphotoxin $alpha$ (LT $alpha$ ),¹ and independently of the presence of the p55TNF-R. These resultsestablish an independent role for induced production of the p75TNF-Rin inflammatory disease pathogenesis and suggest that antagonisticintervention with the functioning of this receptor may potentiallybe beneficial in a wide range of associated human pathologies.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Transgenic and Knockout Mice.

The hup75TNF-R gene was isolated from a human genomic P1-bacteriophage library by PCR screening (Genome Systems Inc., St.Louis, MO) using the primers 5'-CAT CCC TGG GAA TGC-3' and 5'-GAAGAG CGA AGT CGC-3' that amplify a 214-bp region of hup75TNF-RcDNA. A SalI-NotI fragment of ~70 kb containing both 5' and 3'sequences from the hup75TNF-R cDNA was prepared by centrifugationon a 5-25% (wt/vol) NaCl gradient and microinjected into CBA/C57BL/6Jfertilized eggs, as described elsewhere (34). To identify transgenicfounder mice, DNA was isolated from tail biopsies, digested withSac I, and hybridized with a 640-bp XhoI-BglII fragment of hup75cDNA. Transgenic progenies were identified by Southern and slotblot hybridization analysis. TNF (6), LT $alpha$ (35; The JacksonLaboratory, Bar Harbor, ME), p55TNF-R (9; provided by Dr. Bluethmann,Hoffman-La Roche, Nutley, NJ), or p75TNF-R (18; provided by Dr.Moore, Genentech Inc., South San Francisco, CA) knockout micewere maintained on a mixed 129Sv × C57Bl/6 genetic backgroundin the animal facilities of the Hellenic Pasteur Institute.

RNA Preparation and Analysis.

Total RNA was extracted from freshly dissected mouse tissues and S1 nuclease protection analysis was performed as describedpreviously (36) by hybridizing 25 µg of total RNA to a 3-kb5'-³²P-end-labeled BglII probe derived from the 5'-end of the hup75TNF-RcDNA plus vector sequences. Correct initiation of transcriptionfrom the hup75TNF-R gene produces a mRNA that protects 590 ntof the probe from S1 digestion. Endogenous mouse p75TNF-R expressionwas monitored by a 3.7 kb 5'-³²P-end-labeled BglII probe derived from the 5'-end of mup75TNF-RcDNA plus vector sequences (protected fragment 137 bp). A 5'-end-labeled $beta$ -actin DNA probe (protected fragment 110 bp) was used to controlfor quantitative differences between RNA preparations.

Thymocyte Proliferation Assay.

Freshly isolated murine thymocytes from 5-wk-old mice were cultured in 96-well flat-bottomed culture plates (6 × 10⁵/0.1 ml; Costar Corp., Cambridge, MA) in DMEM medium supplementedwith 5% FCS (Globepharm Ltd, Esher, UK), L-glutamine, penicillin,streptomycin, nonessential amino acids (GIBCO BRL, Gaithersburg,MD) and 2-mercapto-ethanol (Sigma Chemical Co., La Verpilliere,France) in the presence of 1 µg/ml Con A (Sigma Chemical Co.).Human rTNF (specific activity 6 × 10⁷ U/mg) was provided by the Genentech manufacturing group (GenentechInc., South San Francisco, CA). Con A and human rTNF were addedto a final volume of 0.2 ml. After 60 h at 37°C, cultures werepulsed with 1 µCi of [³H]thymidine (25 Ci/mmol, 1 mCi = 37 MBq; Amersham Life ScienceLtd, Little Chalfont, UK) for 18 h and harvested onto glass fiberfilters (Skatron Instruments, Lier, Norway). [³H]thymidine incorporation (cpm) of triplicate cultures was determinedusing a liquid scintillation counter (LKB Wallac, Turku, Finland).

TNF and LPS Administration.

Recombinant human TNF (Genentech Inc.) was administered intravenously at 60-150 µg/ mouse in 0.2 ml of PBS. Susceptibilityto LPS was assessed by injecting mice (10-12 wk of age) intraperitoneallywith 200-1,200 µg/25 g of body weight with LPS (Salmonella enteritis;Sigma Chemical Co.) in 0.2 ml saline. Control and transgenic miceare littermates. Lethality was monitored for 5 d and indicatedas lethality/total injected mice.

Flow Cytometry.

Freshly isolated murine thymocytes were adjusted to 2 × 10⁶ cells/ml in DMEM (GIBCO BRL) supplemented as described above andactivated with 1 µg/ml Concanavalin A (Sigma Chemical Co.) for24 h at 37 ° C. Whole blood was collected in heparinized tubesfollowed by erythrocyte depletion. To determine the expressionof murine or human p75TNF-R on thymocytes or whole blood cells,10⁶ cells were stained with a specific anti-mup75TNF-R antibody (rabbitpolyclonal biotin-conjugated 1:600, provided by Dr. Wim Buurman,University of Limburg, The Netherlands) or a specific anti-hup75TNF-Rantibody (M80, rabbit polyclonal 1:500, provided by Dr. MatthiasGrell, University of Stuttgart; reference 37) in 100 µl PBA(0.1% BSA, 0.01% sodium azide in PBS) for 30 min at 4°C. Aftertwo washes with PBS, cells were incubated either by streptavidine-phycoerythrine(1:1,000; PharMingen, San Diego, CA) to detect mup75TNF-R or phycoerythrine-conjugatedanti-rabbit IgG (1:100; Vector Laboratories, Inc., Burlingame,CA) to detect hup75TNF-R. Cells were analyzed on a Becton DickinsonCalibur flow cytometer, using the CellQuest software (Becton Dickinson& Co., Sparks, MD).

ELISA for Murine and Human p75TNF-R.

Serum was collected 6 h after intraperitoneally injections of 100 µg LPS (Salmonella enteritis; Sigma Chemical Co.). The ELISAassays for murine and human p75TNF-Rs were provided by Dr. WimBuurman and performed as described earlier (38). In brief, 96-wellImmuno-Maxisorp Plates (Nunc, Roskilde, Denmark) were coated overnightat 4°C with polyclonal antibodies specific for either receptor.Sera and standard titration samples were incubated for 2 h atroom temperature. Subsequently, plates were incubated with biotin-labeledrabbit polyclonal anti-murine or anti-human p75TNF-R antibodies,followed by a final incubation with Horseradish Peroxidase Streptavidin(Vector Laboratories Inc.). ELISA was developed with 100 µl of0.5 mg/ml O-phenyldiamine dihydrochloride (Sigma Chemical Co.)containing 0.03% H₂O₂, and the reaction was terminated with 50µl of 2 nM H₂SO₄. OD₄₉₀was measured using a MRX microplate Reader(Dynatech, Chantilly, VA).

Histopathology and Immunocytochemistry.

Tissues from freshly dissected mice were immersion-fixed overnight in neutral buffered formalin and embedded in paraplast(BDH Laboratory Supplies, Dorset, UK). Sections were cut and stainedwith hematoxylin and eosin according to standard procedures, dehydratedand mounted in DPX (BDH Laboratory Supplies).

Immunocytochemical analysis was performed on splenic cryostat sections. Immediately before use, sections were fixed for 10min in acetone containing 0.03% H₂O₂ to block endogenous peroxidaseactivity. For double immunostaining for IgM and CD3, sectionswere rehydrated in PBS and incubated with peroxidase-labeled goatanti-mouse IgM Ab (Sigma Chemical Co.) and rat anti-mouse CD3mAb (clone KT [39] provided by Dr. S. Cobbold, Sir William DunnSchool of Pathology, Oxford, UK) for 3 h at room temperature.Subsequently, sections were incubated with biotin-conjugated anti-ratIgG antibody (Southern Biotechnology Associates Inc., Birmingham,AL) followed by streptavidin-alkaline phosphatase (Vector Laboratories).Bound peroxidase activity was detected by staining with diaminobenzidine(DAB; Sigma Chemical Co.), and alkaline phosphatase activity wasvisualized with Fast Blue BB Base (Sigma Chemical Co.).

Nuclear Extract Preparation and Electrophoretic Mobility Shift Assays.

Blood was collected by cardiac puncture in heparinized tubes and PBMC were isolated by centrifugation on Histopaque-1077 gradient(Sigma Chemical Co.) according to the manufacturer's instructions.The mononuclear band was aspirated, washed with PBS, and analyzedmicroscopically.

Nuclear proteins were harvested by the method of Dignam (40). 2 × 10⁶ PBMC were lysed in 1 vol of cold buffer A (10 mM Hepes, pH 7.9,1.5 mM MgCl₂, 10 mM KCl, 0.5 mM DTT, 0.5 mM PMSF, 10 µg/ml aprotinin,10 µg/ml leupeptin, and 10 µg/ml type I-S soybean trypsin inhibitor),incubated for 15 min on ice and centrifuged in an Eppendorf microcentrifugefor 20 s at highest speed. The pellet was resuspended in 2/3 volof cold buffer C (20 mM Hepes, pH 7.9, 420 mM NaCl, 1.5 mM MgCl₂,0.2 mM EDTA, 25% glycerol, 0.5 mM dithiothreitol (DTT), 0.5 mMPMSF, 10 µg/ml aprotinin, 10 µg/ml leupeptin, and 10 µg/ml typeI-S soybean trypsin inhibitor), incubated on ice for 30 min, andcentrifuged for 5 min, 4°C, at highest speed. The supernatantwas quick frozen at $-$ 80°C. Total protein concentration was determinedaccording to the Bradford method (41).

Electrophoretic mobility shift assays were performed by incubating 10 µg of nuclear extract with 4 µg of poly (dI-dC; SigmaChemical Co.) in a binding buffer (5 nM Hepes, pH 7.9, 5 nM MgCl₂,50 mM KCl, 0.5 mM DTT, and 10% glycerol), at 20 µl final volume,for 20 min at RT. An end-labeled, double-stranded, NF- $kappa$ B-specificoligonucleotide probe (MWG-Biotech, Ebersberg, Germany) containingthe two tandemly arranged NF- $kappa$ B binding sites of the human immunodeficiencyvirus long terminal repeat (5'-ATC AGG GAC TTT CCGCTG GGG ACTTTC CG-3') was used to assay for NF- $kappa$ B binding activity (10),whereas an end-labeled double-stranded OCT1-specific oligonucleotideprobe 5'-TGT CGA ATG CAA ATC ACT AGA A-3' (MWG-Biotech) was usedas an internal quantitative control. Specificity of binding wasascertained by competition with a 150-fold molar excess of coldconsensus NF- $kappa$ B or OCT1 oligonucleotides. Protein-DNA complexeswere separated from the free DNA probe by electrophoresis through6% native polyacrylamide gels.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Transgene Expression Patterns and Protein Production in Human p75TNF-R Transgenic Mice.

The hup75TNF-R gene was isolated from a human genomic P1-bacteriophage library by PCR screening (Genome Systems Inc., St.Louis, MO). A large SalI-NotI insert of ~70 kb, was found to containboth 5' and 3' sequences from the hup75TNF-R cDNA and was usedfor transgenesis. Three transgenic lines were generated (TgE1322,TgE1334, and TgE1335) carrying various transgene copy numbers.The integrity of the inserted DNA was confirmed by Southern hybridizationanalysis (not shown). To assess whether regulation and tissuepatterns of transgene expression were physiologically relevant,steady state hup75TNF-R mRNA levels were measured by S1-nucleaseprotection assays on total RNA from several transgenic tissues.Correctly initiated hup75TNF-R-specific transcripts could be detectedin several tissues examined from transgenic mouse lines TgE1334and TgE1335 (Fig. 1) or TgE1322 (not shown). Patterns of expressionwere comparable to those seen for the endogenous p75TNF-R mRNAwith the highest levels seen in lymphoid tissues, liver, and lung(Fig. 1). Overall levels of transgene expression differed betweenlines and were dependent on transgene copy number. TgE1334 micecarrying low transgene copy numbers expressed lower levels ofhuman p75TNF-R compared with the higher transgene copy numberTgE1335 (Fig. 1) or TgE1322 mice (not shown). These results indicatethat important cis-acting regulatory elements controlling theexpression of the hup75TNF-R gene were included in the microinjectedfragment and that correctly regulated patterns of transgene expressioncould be established in these transgenic mice.

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Fig. 1. S1 nuclease protection analysis of total RNA from tissues of normal, TgE1334 and TgE1335 mice shows correct patterns of expression for the transgenic p75TNF-R mRNA. $beta$ -actin acts as an internal control for sample loading.

Expression of cell surface p75TNF-Rs was assessed by flow cytometric analysis on ConA-activated transgenic thymocytes andon freshly isolated peripheral blood cells. Similar to the expressionof murine p75TNF-R on normal activated thymocytes, induced expressionof human p75TNF-R could be observed on the surface of ConA- activatedtransgenic thymocytes (Fig. 2 A), indicating correct regulationof the hup75TNF-R protein production. Moreover, transgenic PBMC(not shown) or total peripheral blood leukocytes were also foundto express on their surface the human p75TNF-R protein (Fig. 3B). Furthermore, using double immunostaining of liver sectionswith F4/80 and anti-p75TNF-R antibodies, the kupffer cell wasidentified as a source of both endogenous or transgenic p75TNF-Rs(not shown).

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Fig. 2. Production of a functional hup75TNF-R protein on the surface of transgenic thymocytes. (A) Freshly isolated or ConA-stimulated thymocytes from normal, TgE1335, and mup75TNF-R knockout mice were analyzed by flow cytometry for the expression of murine and human p75TNF-R protein. Approximately 20 and 22% of freshly isolated normal and transgenic thymocytes were found to express endogenous or transgenic p75TNF-R, respectively. ConA stimulation resulted in the induction of both the murine p75TNF-R in normal mice (60% of cells positive) and the human p75TNF-R in transgenic mice (57% of cells positive). Thymocytes from normal or p75TNF-R-deficient mice are used as negative controls. (B) Proliferative response of ConA-treated TgE1335 ( $bullet$ ) and normal ( $open circle$ ) thymocytes to human rTNF reveals a functional human p75TNF-R protein. The amount of ³H incorporation in either normal or transgenic thymocytes treated with ConA alone is indicated by a dashed line. Results are representative of three independent experiments.

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Fig. 3. Production of soluble and cell surface hup75TNF-R protein in transgenic sera and on peripheral blood leukocytes. (A) Serum levels of soluble mup75 and hup75TNF-Rs were measured by specific ELISAs, before or after LPS-administration in normal (n = 4), and TgE1335 heterozygous (n = 4) mice. Total (murine and human) sp75TNF-R production in heterozygous TgE1335 mice is increased approximately fivefold in comparison to the production of endogenous sp75TNF-R protein in normal mice (49 ± 4.5 ng/ml total p75TNF-R protein in transgenic mice versus 10 ± 2.5 ng/ml of endogenous p75TNF-R protein in normal mice). Transgenic p75TNF-R production in LPS-treated TgE1335 mice is regulated similarly to normal LPS-treated mice. TgE1335 homozygous mice (n = 4) spontaneously produce highly elevated levels of both soluble murine and human p75TNF-Rs. (B) Flow cytometric analysis of peripheral blood leukocytes from 3-wk-old TgE1335 heterozygous or homozygous mice shows the enhanced surface expression of hup75TNF-R on leukocytes taken from homozygous transgenic animals. Data are representative of three independent experiments.

Serum levels of soluble human and murine p75TNF-Rs (sp75TNF-R) were measured in TgE1334 and TgE1335 transgenic mice beforeor after stimulation by LPS (38). Both transgenic lines wereshown to produce in their serum human sp75TNF-R. TgE1334 miceproduced the transgenic receptor at levels comparable to the endogenoussp75TNF-R in normal control mice (~10 ± 2.5 ng/ml for either receptor,not shown), whereas TgE1335 mice expressed an overall three- tofourfold increased levels of transgenic sp75TNF-R (~33 ± 4.3 ng/mlof transgenic versus 10 ± 2.5 ng/ml of the endogenous in normalmice, Fig. 3 A). After challenge by LPS in vivo, human and murinesp75TNF-R levels were comparable in heterozygous TgE1334 (notshown) and TgE1335 mice versus normal control mice (Fig. 3 A),indicating correct regulation by LPS of the exogenous p75TNF-Rprotein production and shedding. Interestingly, nonchallengedhomozygous TgE1335 mice produce the transgenic hup75TNF-R proteinat levels similar to those seen for endogenous p75TNF-R in LPS-treatednormal control mice (Fig. 3 A).

The functional integrity of the human p75TNF-R protein was assessed by measuring its activity in a thymocyte proliferationassay (42). Transgenic but not normal control thymocytes wereinduced to proliferate by exogenous recombinant human TNF demonstratingthe presence of a functional human p75TNF-R (Fig. 2 B). Takentogether, these results demonstrate that correctly regulated andphysiologically relevant expression of a functional human p75TNF-Rprotein was established in these transgenic mice.

Enhanced hup75TNF-R Expression Sensitizes Mice to the In Vivo Toxicity of rhuTNF and LPS.

Previous studies in p75TNF-R knockout mice have indicated an enhancing role for this receptor in the lethal toxicity of LPSor murine TNF (18). Additional studies however, have suggesteda neutralizing potential of enhanced levels of soluble TNF-Rsin models of endotoxemia (38, 43). To assess whether expressionof a human p75TNF-R protein would render mice more resistant ormore susceptible to LPS or huTNF administration, and to determinethe net in vivo effect of hup75TNF-R overexpression in endotoxemicmice, we measured lethality rates in Tg1335 and control animalschallenged intravenously or intraperitoneally with different dosesof recombinant huTNF or LPS respectively. Table 1 summarizesthe results of these experiments. Human p75TNF-R expression isshown to potently sensitize transgenic mice to the toxicity ofan otherwise sublethal dose of either rhuTNF (90 µg) or LPS (800µg), demonstrating that induced production of the hup75TNF-R proteincontributes positively to the lethal outcome of endotoxemia.

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Table 1
Human p75TNF-R Transgenic Mice Are More Susceptible to Lethality After Administration of Human rTNF or LPS

Sustained Overproduction of the p75TNF-R Triggers Multi-organ Inflammatory Pathology.

Mice heterozygous for the hup75TNF-R transgene from all three transgenic lines develop and grow normally and display no pathologicalchanges with the exception of mice from the highest expressingline TgE1335 that develop a chronic but mild peri-vascular inflammatorypathology in liver, pancreas, and lung at 2-3 mo of age (Fig.4). Notably, homozygous TgE1335 or TgE1322 mice develop a severepathology characterized by runting, lethargy, and abdominal distensionand accompanied by a severely reduced weight gain (data not shown).The disease leads to the premature death of these animals between2 and 4 wk of age. At necropsy of 20-d-old homozygous TgE1335mice, thymic and pancreatic atrophy, splenomegaly, and extensiveliver necrosis were observed. Histopathological analyses revealedheavy peri-vascular inflammatory lesions in several organs suchas pancreas, liver, lung, and kidney. In addition to heavy inflammation,extensive ischemic tissue necrosis could be observed in the liver(Fig. 4). Other organs and sites such as muscle and brain meningeswere also inflammatory in homozygous animals. Infiltrates in heterozygousTgE1335 animals consisted mainly of T and B cells, macrophages,and polymorphonuclear cells as assessed by immunocytochemicalanalysis using cell-specific markers (not shown). Interestingly,although a similar infiltrate was present in the heavily inflamedorgans of 2-wk-old homozygous TgE1335 mice, a striking absenceof B220-positive B cells was observed (not shown). IgM⁺ B cells were also shown to be markedly decreased in sectionsof spleens from homozygous TgE1335 mice (Fig. 4). FACS^®-analysis performed in peripheral blood, spleen, and bone marrowcells of homozygous TgE1335 mice confirmed the almost completeabsence of B220⁺IgM and B220⁺IgM⁺ B cells, indicating impaired B cell development. In contrast,mature CD4⁺ and CD8⁺ single positive as well as Mac1⁺/Gr1⁺ cells could readily be detected in both the inflammatory infiltratesand in spleen and blood of homoTgE1335 mice (not shown).

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Fig. 4. p75TNF-R-triggered multi-organ inflammation and hematopoietic abnormalities develop even in the absence of TNF. Histopathological analysis (H/E) in liver and pancreas of 4-mo-old heterozygous TgE1335 mice (TgE1335het) and 3-wk-old TgE1335 homozygous (TgE1335hom) or homozygous TgE1335 × TNF^/ mice (TgE1335hom/TNF^/). Lesions in heterozygous Tg1335 mice involve mainly the liver and pancreas where inflammatory infiltrates develop and persist chronically from 2-3 mo of age. In homozygous TgE1335 mice a more severe pathology develops, characterized by extensive periportal inflammation and tissue necrosis (asterisk) in the liver, and in a severely hypoplastic and inflamed pancreas. A similar histopathology evolves in homozygous TgE1335 transgenic mice bred into a null TNF background. Original magnification ×108. Spleen sections from homozygous TgE1335 mice are characterized by markedly reduced numbers of IgM⁺ B cells (brown) whereas CD3⁺ T cell localization (blue) seems unaffected. A similar phenotype occurs even in the absence of endogenous TNF. Original magnification ×114.

p75TNF-R-induced Pathology Develops Even in the Absence of TNF, LT $alpha$ or the p55TNF-R.

To examine the dependency of the observed p75TNF-R-mediated pathology on the presence of the TNF or LT $alpha$ ligands, and to evaluatethe contribution of a cooperation of the human p75TNF-R with theendogenous p75 or p55TNF-Rs, we have introduced the hup75TNF-Rtransgene, as a homozygous trait, into genetic backgrounds deficientin either TNF (6), LT $alpha$ (35), the p75TNF-R (18), or thep55TNF-R (9). In all four deficient backgrounds, homozygousTgE1335 mice developed fully the lethal multi-organ pathology.Increased levels of the human p75TNF-R are therefore sufficientto induce disease even in the absence of the p55TNF-R (Fig. 5).Most importantly, the pathogenic potential of the human p75TNF-Rcould be exerted independent of the presence of TNF (Figs. 4 and5) or LT $alpha$ (not shown). Interestingly, however, although the p55TNF-Rand LT $alpha$ were dispensable for the development of pathology, a lowbut measurable pathogenic contribution of the endogenous TNF couldbe observed, since in TNF-deficient backgrounds homozygous TgE1335mice do succumb to disease but with a delay of a few weeks (Fig.5). A measurable delay in disease progression was also evidentin the absence of the endogenous p75TNF-R (not shown), especiallyat the histopathological level where homoTgE1335/ p75TNF-R^/ mice displayed a generally milder phenotype (e.g., fewer inflammatoryinfiltrates in several organs and no evidence for necrosis inliver) in comparison to homoTgE1335 controls, confirming thatdevelopment of pathology correlates with the level of p75TNF-Rsbeing produced. Consistent with the enhancing pathogenic involvementof endogenous TNF, diseased homozygous TgE1335 mice show dramaticallyincreased levels of endogenous TNF in their sera (1.09 ng/ml ±0.15, n = 4). Notably, a similar lethal multi-organ inflammatorydisease could be triggered at 4-8 wk of age, even in the absenceof the p55TNF-R (i.e., in a p55TNF-R knockout background), inheterozygous TgE1335 mice bred with otherwise healthy transgenicmice overexpressing T cell targeted human wild-type (Tg7; reference15), or transmembrane TNF (Tg5453; reference 16; not shown).This result shows that in this model, the pathogenic contributionof TNF results from direct interaction with the p75TNF-R and doesnot necessitate a functional p55TNF-R. The lethal phenotype ofthe Tg7/TgE1335 double heterozygotes, but not the baseline inflammatorycomplications of the heterozygous TgE1335 line could be completelyneutralized by preventive treatment of mice with a specific anti-humanTNF antibody (CB0006; Celltech Therapeutics Ltd, Slough, UK; notshown). These results demonstrate that, in vivo, the p75TNF-Rmediates inflammatory signals independently of the presence orcoactivation of the p55TNF-R. Moreover, although the presenceof TNF could further enhance the spontaneous inflammatory activitiesof the p75TNF-R, its role in the activation of these deleteriousfunctions was nonessential.

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Fig. 5. Survival of hup75TNF-R transgenic mice in the absence of TNF or the p55TNF-R. All TgE1335 heterozygous mice (Tghet, n = 10, $open circle$ ) survive usually past 10 mo of age whereas TgE1335 homozygous mice (Tghom, n = 10, $bullet$ ) succumb to the disease during their first month of age even in the absence of the p55TNF-R (Tghom/p55^/, n = 6, $triangle$ ). The presence of TNF contributes positively but is not essential for the development of the lethal pathology (Tghom/TNF^/, n = 10, $black-square$ ). Survival is measured as a percentage of the initial number of animals in each genotype group.

Enhanced NF- $kappa$ B Binding Activity in Nuclear Extracts of PBMC from hup75TNF-R Transgenic Mice.

NF- $kappa$ B activation is believed to be important in the triggering of proinflammatory cytokine cascades (44) and it has recentlybeen shown that in vivo NF- $kappa$ B activation in PBMC plays an importantrole in the lethality accompanying LPS-induced endotoxemia inmice (32). On the other hand, signaling through the p75TNF-Ris known to involve NF- $kappa$ B activating pathways (45). Therefore,it was important to assess the activation status of the NF- $kappa$ Bsystem in the p75TNF-R transgenic mice. NF- $kappa$ B binding activitywas determined by EMSA in nuclear extracts of PBMC from heterozygousTgE1335 mice at different developmental points. NF- $kappa$ B bindingactivity was found consistently elevated in PBMC from transgenicversus control mice (Fig. 6), either before (1 mo of age), during(2 mo), or after (6 mo) development of pathology, as assessedby simultaneous histopathological analysis of all experimentalmice (not shown). These results suggest that a possible targetpathway of sustained p75TNF-R activation in PBMC is the NF- $kappa$ Bpathway and offer a mechanistic link to explain the observed invivo inflammatory activities of this receptor.

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Fig. 6. Enhanced NF- $kappa$ B binding activity in PBMC from hup75 transgenic mice. EMSA of nuclear extracts from PBMC isolated from heterozygous TgE1335 mice or normal control littermates (n = 5 per group) at 1, 2, and 6 mo of age. Specific NF- $kappa$ B complexes are indicated by arrows, whereas OCT-1 probe acts as an internal control for sample loading. Cold NF- $kappa$ B or OCT-1 probe was used to indicate specific NF- $kappa$ B or OCT-1 binding, respectively.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

Circulating levels of soluble TNF-Rs are constantly elevated in a variety of clinical conditions including malignant (46),infectious, and sub-acute or chronic inflammatory or autoimmunediseases (33, 47). In several of these conditions, measurementof sTNF-Rs, especially of the sp75TNF-R, correlates even betterthan classical disease-specific markers to the prognosis, symptoms,and clinical outcome of the disease (33). For example, sTNF-Rlevels have a strong and early prognostic value for disease progressionin HIV-infected patients (30) and in several inflammatory diseasessuch as chronic hepatitis virus infections (25), acute pancreatitis(27), acute respiratory distress syndrome (26), SLE (28),and rheumatoid arthritis (29). The actual involvement of solubleTNF receptors in disease pathogenesis remains controversial andit has been suggested that they may act both as antagonists ofTNF action by competing with its cell surface receptors, but alsoas agonists by protecting TNF from degradation and therefore stabilizingand enhancing its activity (47). Shedding of both TNF receptorsoccurs in both a constitutive and inducible manner, after appropriatestimulation by a plethora of immune activating signals, and inaddition to providing the soluble receptors it is thought to servein rendering cells temporarily unresponsive to TNF (47). However,a correlation of induced sTNF-R levels with enhanced expressionof their cell surface precursors in specific cell types remainspossible, especially in the case of the p75TNF-R, the expressionof which is known to be highly inducible by the same signals thatmediate its induced shedding (38, 47). Indeed, as shown clearlyin this study, sustained upregulation of human p75TNF-R productionin transgenic mice, leads to both an upregulated level of shedsoluble receptors but also to a chronic accumulation of the receptoron the cell surface. Therefore, it is possible that increasedlevels of shed p75TNF-Rs, as seen in human diseases, reflect asimilar upregulation of the cell surface form of the receptor,which may interfere with immune homeostasis and/or pathogenesis.

Notably, the severity of the inflammatory phenotypes developing in transgenic lines expressing hup75TNF-R transgenes correlatespositively with the levels of soluble human p75TNF-R measuredin diseased sera. For example, heterozygous TgE1334 mice constitutivelyexpressing only double the physiological levels of p75TNF-Rs donot show any signs of pathology, whereas heterozygous TgE1335mice producing four- to fivefold higher levels develop a chronicinflammatory disease. On the other hand, homozygous TgE1335 micedeveloping a most severe multi-organ inflammatory phenotype arefound to constitutively produce twofold increased levels of totalsp75TNF-Rs in comparison to the levels measured for endogenousp75TNF-Rs in sera from endotoxemic (LPS-treated) mice (Fig. 3A). Interestingly, serum sp75TNF-R levels measured in severalhuman inflammatory diseases, including AIDS, are usually two-to fourfold increased over normal individuals (25), whereaseven higher levels have been recorded in septic shock patients(24). Taken together, our results show that at levels similarto those seen in human disease, chronic induced production ofthe p75TNF receptor in vivo, has detrimental effects to physiologicalhomeostasis and leads to a multi-organ inflammatory syndrome inmice. Furthermore, they demonstrate that the severity of the invivo proinflammatory activities of the p75TNF-R correlate positivelywith its chronic level of production.

Although our current knowledge of the involvement of the TNF/p55TNF-R pair in disease pathogenesis is quite advanced, understandingof the in vivo function of the p75TNF-R remains vague. Recentstudies in p75TNF-R knockout mice have failed to show a specificfunction for this receptor in physiology or in experimental modelsof TNF-mediated disease (18, 48) with the exception of itsprofound involvement in the cerebral complications of experimentalmalaria (49) or in the allergen-induced migration of Langerhanscells (50). Moreover, in view of the almost uniquely known invitro activities of this receptor on thymocyte/T lymphocyte proliferation(42), or in the activation induced apoptosis of CD8⁺ T cells (51), it was quite surprising that thymocytes and lymphocytesin p75TNF-R knockout mice were normal (18). The failure to demonstratean in vivo independent activity of the p75TNF-R in the knockoutsystem, together with ample evidence for a partial agonistic roleof this receptor in TNF/p55TNF-R-mediated responses (14, 52,53) has led to the hypothesis that the p75TNF-R serves an accessoryrole in enhancing p55TNF-R-mediated signaling. Interestingly,in all cases where p75TNF-R-specific signaling has been observed,a high density of this receptor on the cell surface was required,suggesting that inducibility of this receptor is a prerequisitefor function (21, 22). Activation of receptors through inducedaggregation is a widespread phenomenon in cytokine and growthfactor signaling (54, 55). Ligand-induced clustering of receptorsseems to be a primary control mechanism, in particular for constitutivelyproduced receptors, such as the p55TNF-R. On the other hand, thereis substantial evidence in vitro, that induced production of suchmembers of the TNF-R family as the p75 (45, 56) or the p55TNF-R(57), Fas (57), CD40 (45, 58), or p75NGF-R (59) andthe tyrosine kinase receptors for growth factors (60) may leadto spontaneous signaling even in the absence of ligand. Our presentdata are in support of a physiologically significant role forligand-independent signaling in vivo, especially for the p75TNF-Rwhich is known to be highly induced in pathological conditions.However, it remains possible that yet unidentified ligands maycontribute to its observed activation.

Our evidence that sustained p75TNF-R overproduction in mice may lead to inflammatory complications involving several vitaltissues and organs, has important implications for inflammatorydisease pathogenesis in humans. Interestingly, in a recent studyaddressing kinetics of production of soluble TNF-R after leakageof high doses of TNF in the circulation of patients undergoingisolated limb perfusion therapy (31), it has been observed thatlevels of soluble p75TNF-R remain high, long after TNF disappearsfrom the circulation, suggesting a TNF-independent regulationof the production and perhaps function of this receptor. The surprisingfinding in this study, that the inflammatory activities of thep75TNF-R occur even in the absence of TNF, offers a novel mechanismfor p75TNF-R functioning which may be of pivotal importance inmany clinical conditions including sepsis. It is important tonote that although the TNF/p55TNF-R system seems to operate onlyin an initial narrow window of time during clinical sepsis (61),sp75TNF-R levels are found constantly elevated, correlate positivelywith sepsis scores and show maximal values in patients that donot survive (24). After the disappointing neutral outcome ofanti-TNF trials in sepsis, and taking into account the adverseeffects of enhanced p75TNF-R production as presented in this study,it is tempting to speculate that specific antagonism of this receptormay be beneficial even at late phases of severe sepsis, but alsoduring the course of many other human inflammatory pathologieswhere a positive correlation between soluble p75TNF-R and diseaseprogression has been observed. The human p75TNF-R expressing transgeniclines presented in this study should offer a useful model systemto develop and test the in vivo efficacy of such p75TNF-R antagonisticsubstances.

	Footnotes

Address correspondence to George Kollias, Department of Molecular Genetics, Hellenic Pasteur Institute, 127 Vas. Sophias Avenue, 115 21 Athens, Hellas. Tel.: 30 1 6455071. Fax: 30 1 6456547. E-mail: giorgos_kollias{at}hol.gr

Received for publication 19 June 1998 and in revised form 29 July 1998.

This project was supported in part by the Hellenic Secretariat for Research and Technology and European Commission GrantsBIO4-CT96-0077 and BIO4-CT96-0174.

We wish to thank Dr. Horst Bluethmann for providing the p55TNF-R knockout mice; Dr. Mark Moore for providing the p75TNF-Rknockout mice; the Genentech manufacturing group for the recombinanthuman TNF; Dr. Matthias Grell for the M80 polyclonal anti-humanp75TNF-R antibody; Dr. Wim Buurman for the murine and human p75TNF-R-specificELISA; Dr. Steve Cobbold for the KT3 anti-CD3 antibody; Dr. RolyFoulkes for the CB0006 anti-human TNF antibody; Dr. StavroulaKousteni for helpful advice on EMSA protocols; and finally SpiridoulaPapandreou and Spiros Lalos for excellent technical assistance.

Abbreviations used in this paper DAB, diaminobenzidine; DTT, dithiothreitol; LT $alpha$ , lymphotoxin $alpha$ .

	References

Top Abstract Introduction Materials & Methods Results Discussion References

1.	Vassalli, P.. 1992. The pathophysiology of tumor necrosis factors. Annu. Rev. Immunol. 10: 411-452 [Medline].
2.	Vandenabeele, P., W. Declercq, R. Beyaert, and W. Fiers. 1995. Two tumour necrosis factor receptors: structure and function. Trends Cell. Biol. 5: 392-399 . [Medline]
3.	Aggarwal, B.B., and K. Natarajan. 1996. Tumor necrosis factors: Developments during the last decade. Eur. Cytokine Netw. 7: 93-124 [Medline].
4.	Seckinger, P., S. Isaaz, and J.M. Dayer. 1989. Purification and biologic characterization of a specific tumor necrosis factor a inhibitor. J. Biol. Chem. 264: 11966-11973 [Abstract/Free Full Text].
5.	Engelmann, H., D. Novick, and D. Wallach. 1990. Two tumor necrosis factor-binding proteins purified from human urine. Evidence for immunological cross-reactivity with cell surface tumor necrosis factor receptors. J. Biol. Chem. 265: 1531-1536 [Abstract/Free Full Text].
6.	Pasparakis, M., L. Alexopoulou, V. Episkopou, and G. Kollias. 1996. Immune and inflammatory responses in TNF $alpha$ -deficient mice: a critical requirement for TNF $alpha$ in the formation of primary B cell follicles, follicular dendritic cell networks and germinal centers, and in the maturation of the humoral immune response. J. Exp. Med. 184: 1397-1411 [Abstract/Free Full Text].
7.	Le Hir, M., H. Bluethmann, M.H. Kosco-Vilbois, M. Muller, F. Di Padova, M. Moore, B. Ryffel, and H.P. Eugster. 1996. Differentiation of follicular dendritic cells and full antibody responses require tumour necrosis factor receptor-1 signalling. J. Exp. Med. 183: 2367-2373 [Abstract/Free Full Text].
8.	Neumann, B., T. Machleidt, A. Lifka, K. Pfeffer, D. Vestweber, T.W. Mak, B. Holzmann, and M. Kronke. 1996. Crucial role of 55-kilodalton TNF receptor in TNF-induced adhesion molecule expression and leukocyte organ infiltration. J. Immunol. 156: 1587-1593 [Abstract].
9.	Rothe, J., W. Lesslauer, H. Lotscher, Y. Lang, P. Koebel, F. Kontgen, A. Althage, R. Zinkernagel, M. Steinmetz, and H. Bluethmann. 1993. Mice lacking the tumour necrosis factor receptor 1 are resistant to TNF-mediated toxicity but highly susceptible to infection by Listeria monocytogenes. Nature. 364: 798-802 [Medline].
10.	Pfeffer, K., T. Matsuyama, T.M. Kundig, A. Wakeham, K. Kishihara, A. Shahinian, K. Wiegmann, P.S. Ohashi, M. Kronke, and T.W. Mak. 1993. Mice deficient for the 55kd tumor necrosis factor receptor are resistant to endotoxic shock, yet succumb to L. monocytogenes infection. Cell. 73: 457-467 [Medline].
11.	Ruby, J., H. Bluethmann, and J.J. Peschon. 1997. Antiviral activity of tumor necrosis factor (TNF) is mediated via p55 and p75 TNF receptors. J. Exp. Med. 186: 1591-1596 [Abstract/Free Full Text].
12.	Douni, E., K. Akassoglou, L. Alexopoulou, S. Georgopoulos, S. Haralambous, S. Hill, G. Kassiotis, D. Kontoyiannis, M. Pasparakis, D. Plows, et al . 1996. Transgenic and knockout analyses of the role of TNF in immune regulation and disease pathogenesis. J. Inflamm. 47: 27-38 .
13.	Akassoglou, K., L. Probert, G. Kontogeorgos, and G. Kollias. 1997. Astrocyte-specific but not neuron-specific transmembrane TNF triggers inflammation and degeneration in the central nervous system of transgenic mice. J. Immunol. 158: 438-445 [Abstract].
14.	Alexopoulou, L., M. Pasparakis, and G. Kollias. 1997. A murine transmembrane tumor necrosis factor (TNF) transgene induces arthritis by cooperative p55/p75 TNF receptor signalling. Eur. J. Immunol. 27: 2588-2592 [Medline].
15.	Probert, L., J. Keffer, P. Corbella, H. Cazlaris, E. Patsavoudi, S. Stephens, E. Kaslaris, D. Kioussis, and G. Kollias. 1993. Wasting, ischemia and lymphoid abnormalities in mice expressing T-cell targeted human tumor necrosis factor transgenes. J. Immunol. 151: 1894-1906 [Abstract].
16.	Georgopoulos, S., D. Plows, and G. Kollias. 1996. Transmembrane TNF is sufficient to induce localized tissue toxicity and chronic inflammatory arthritis in transgenic mice. J. Inflamm 46: 86-97 [Medline].
17.	Kondo, S., and D.N. Sauder. 1997. Tumor necrosis factor (TNF) receptor type 1 (p55) is a main mediator for TNF- $alpha$ -induced skin inflammation. Eur. J. Immunol. 27: 1713-1718 [Medline].
18.	Erickson, S.L., F.J. De Sauvage, K. Kikly, K. Carver-Moore, S. Pitts-Meek, N. Gillett, K.C. Sheehan, R.D. Schreiber, D.V. Goeddel, and M.W. Moore. 1994. Decreased sensitivity to tumour-necrosis factor but normal T-cell development in TNF receptor-2-deficient mice. Nature. 372: 560-563 [Medline].
19.	Grell, M., E. Douni, H. Wajant, M. Lohden, M. Clauss, B. Maxeiner, S. Georgopoulos, W. Lesslauer, G. Kollias, K. Pfizenmaier, and P. Scheurich. 1995. The transmembrane form of tumor necrosis factor is the prime activating ligand of the 80 kDa tumor necrosis factor receptor. Cell. 83: 793-802 [Medline].
20.	Grell, M., H. Wajant, G. Zimmermann, and P. Scheurich. 1998. The type 1 receptor (CD120a) is the high-affinity receptor for tumor necrosis factor. Proc. Natl. Acad. Sci. USA. 95: 570-575 [Abstract/Free Full Text].
21.	Vandenabeele, P., W. Declercq, B. Vanhaesebroeck, J. Grooten, and W. Fiers. 1995. Both TNF receptors are required for TNF-mediated induction of apoptosis in PC60 cells. J. Immunol. 154: 2904-2913 [Abstract].
22.	Haridas, V., B.G. Darnay, K. Natarajan, R. Heller, and B.B. Aggarwal. 1998. Overexpression of the p80 TNF receptor leads to TNF-dependent apoptosis, nuclear factor- $kappa$ B activation, and c-Jun kinase activation. J. Immunol. 160: 3152-3162 [Abstract/Free Full Text].
23.	Santee, S.M., and L.B. Owen-Schaub. 1996. Human tumor necrosis factor receptor p75/80 (CD120b) gene structure and promoter characterization. J. Biol. Chem. 271: 21151-21159 [Abstract/Free Full Text].
24.	Schroder, J., F. Stuber, H. Gallati, F.U. Schade, and B. Kremer. 1995. Pattern of soluble TNF receptors I and II in sepsis. Infection. 23: 143-148 [Medline].
25.	Marinos, G., N.V. Naoumov, S. Rossol, F. Torre, P.Y. Wong, H. Gallati, B. Portmann, and R. Williams. 1995. Tumor necrosis factor receptors in patients with chronic hepatitis B virus infection. Gastroenterology. 108: 1453-1463 [Medline].
26.	Lucas, R., J. Lou, D.R. Morel, B. Ricou, P.M. Suter, and G.E. Grau. 1997. TNF receptors in the microvascular pathology of acute respiratory distress syndrome and cerebral malaria. J. Leukoc. Biol. 61: 551-558 [Abstract].
27.	De Beaux, A.C., J.A. Goldie, D.C. Ross, D.C. Carter, and K.C.H. Fearon. 1996. Serum concentrations of inflammatory mediators related to organ failure in patients with acute pancreatitis. British J. Surgery. 83: 349-353 .
28.	Gabay, C., N. Cakir, F. Moral, P. Roux-Lombard, O. Meyer, J.M. Dayer, T. Vischer, H. Yazici, and P.A. Guerne. 1997. Circulating levels of tumor necrosis factor soluble receptors in systemic lupus erythematosus are significantly higher than in other rheumatic diseases and correlate with disease activity. J. Rheumatol. 24: 303-308 [Medline].
29.	Cope, A.P., D. Aderka, M. Doherty, H. Engelmann, D. Gibbons, A.C. Jones, F.M. Brennan, R.N. Maini, D. Wallach, and M. Feldmann. 1992. Increased levels of soluble tumor necrosis factor receptors in the sera and synovial fluid of patients with rheumatic diseases. Arthritis Rheum. 35: 1160-1169 [Medline].
30.	Godfried, M.H., T. Van der Poll, J. Jansen, J.A. Romijin, J.K. Schattenkerk, E. Endert, S.J. Van Deventer, and H.P. Sauerwein. 1993. Soluble receptors for tumour necrosis factor: a putative marker of disease progression in HIV infection. AIDS (Lond.). 7: 33-36 [Medline].
31.	Aderka, D., P. Sorkine, S. Abu-Abid, D. Lev, A. Setton, A.P. Cope, D. Wallach, and J. Klausner. 1998. Shedding kinetics of soluble tumor necrosis factor (TNF) receptors after systemic TNF leaking during isolated limb perfusion. Relevance to the pathophysiology of septic shock. J. Clin. Invest. 101: 650-659 [Medline].
32.	Bohrer, H., F. Qiu, T. Zimmermann, Y. Zhang, T. Jllmer, D. Mannel, B.W. Bottiger, D.M. Stern, R. Waldherr, H.D. Saeger, et al . 1997. Role of NF- $kappa$ B in the mortality of sepsis. J. Clin. Invest. 100: 972-985 [Medline].
33.	Diez-Ruiz, A., G.P. Tilz, R. Zangerle, G. Baier-Bitterlich, H. Wachter, and D. Fuchs. 1995. Soluble receptors for tumour necrosis factor in clinical laboratory diagnosis. Eur. J. Haematol. 54: 1-8 [Medline].
34.	Pasparakis, M., and G. Kollias. 1995. Production of cytokine transgenic and knockout mice. In Cytokines: A Practical Approach. F. Balkwill, editor. IRL Press, Oxford, UK. 297-325.
35.	De Togni, P., J. Goellner, N.H. Ruddle, P.R. Streeter, A. Fick, S. Mariathasan, S.C. Smith, R. Carlson, L.P. Shornick, J. Strauss-Schoenberger, et al . 1994. Abnormal development of peripheral lymphoid organs in mice deficient in lymphotoxin. Science. 264: 703-707 [Abstract/Free Full Text].
36.	Kollias, G., N. Wrighton, J. Hurst, and F. Grosveld. 1986. Regulated expression of human ^A $gamma$ -, $beta$ -, and hybrid $gamma$ $beta$ -globin genes in transgenic mice: manipulation of the developmental expression patterns. Cell. 46: 89-94 [Medline].
37.	Grell, M., P. Scheurich, A. Meager, and K. Pfizenmaier. 1993. TR60 and TR80 tumor necrosis factor (TNF)-receptors can independently mediate cytolysis. Lymphokine Cytokine Res. 12: 143-148 [Medline].
38.	Bemelmans, M.H., D.J. Gouma, and W.A. Buurman. 1993. LPS-induced sTNF-receptor release in vivo in a murine model. Investigation of the role of tumor necrosis factor, IL-1, leukemia inhibitory factor, and IFN- $gamma$ . J. Immunol. 151: 5554-5562 [Abstract].
39.	Tomonari, K.. 1988. A rat antibody against a structure functionally related to the mouse T-cell receptor/T3 complex. Immunogenetics. 28: 455-458 [Medline].
40.	Dignam, J.D.. 1990. Preparation of extracts from higher eukaryotes. Methods Enzymol. 182: 194-203 [Medline].
41.	Bradford, M.M.. 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem. 72: 248-254 [Medline].
42.	Tartaglia, L.A., D.V. Goeddel, C. Reynolds, I.S. Figari, R.F. Weber, B.M. Fendly, and M.A. Palladino Jr.. 1993. Stimulation of human T-cell proliferation by specific activation of the 75-kDa tumor necrosis factor receptor. J. Immunol. 151: 4637-4641 [Abstract].
43.	Bemelmans, M.H.A., D.J. Gouma, and W.A. Buurman. 1993. Influence of nephrectomy on tumor necrosis factor clearance in a murine model. J. Immunol. 150: 2007-2017 [Abstract].
44.	Baeuerle, P.A., and D. Baltimore. 1996. NF- $kappa$ B: ten years after. Cell. 87: 13-20 [Medline].
45.	Rothe, M., V. Sarma, V.M. Dixit, and D.V. Goeddel. 1995. TRAF2-mediated activation of NF- $kappa$ B by TNF receptor 2 and CD40. Science. 269: 1424-1427 [Abstract/Free Full Text].
46.	Aderka, D., H. Englemann, V. Hornik, Y. Skornick, Y. Levo, D. Wallach, and G. Kushtai. 1991. Increased serum levels of soluble receptors for tumor necrosis factor in cancer patients. Cancer Res. 51: 5602-5607 [Abstract/Free Full Text].
47.	Aderka, D.. 1996. The potential biological and clinical significance of the soluble tumor necrosis factor receptors. Cytokine Growth Factor Rev. 7: 231-240 . [Medline]
48.	Peschon, J.J., D.S. Torrance, K.L. Stocking, M.B. Glaccum, C. Otten, C.R. Willis, K. Charrier, P.J. Morrissey, C.B. Ware, and K.M. Mohler. 1998. TNF receptor-deficient mice reveal divergent roles for p55 and p75 in several models of inflammation. J. Immunol. 160: 943-952 [Abstract/Free Full Text].
49.	Lucas, R., P. Juillard, E. Decoster, M. Redard, D. Burger, Y. Donati, C. Giroud, C. Monso-Hinard, T. De Kesel, W.A. Buurman, et al . 1997. Crucial role of tumor necrosis factor (TNF) receptor 2 and membrane-bound TNF in experimental cerebral malaria. Eur. J. Immunol. 27: 1719-1725 [Medline].
50.	Wang, B., H. Fujisawa, L. Zhuang, S. Kondo, G.M. Shivji, C.S. Kim, T.W. Mak, and D.N. Sauder. 1997. Depressed langerhans cell migration and reduced contact hypersensitivity response in mice lacking TNF receptor p75. J. Immunol. 159: 6148-6155 [Abstract].
51.	Zheng, L., G. Fisher, R.E. Miller, J. Peschon, D.H. Lynch, and M.J. Lenardo. 1995. Induction of apoptosis in mature T cells by tumour necrosis factor. Nature. 377: 348-351 [Medline].
52.	Tartaglia, L.A., D. Pennica, and D.V. Goeddel. 1993. Ligand passing: the 75-kDa tumor necrosis factor (TNF) receptor recruits TNF for signaling by the 55-kDa TNF receptor. J. Biol. Chem. 268: 18542-18548 [Abstract/Free Full Text].
53.	Weiss, T., M. Grell, B. Hessabi, S. Bourteele, G. Muller, P. Scheurich, and H. Wajant. 1997. Enhancement of TNF receptor p60-mediated cytotoxicity by TNF receptor p80: requirement of the TNF receptor-associated factor-2 binding site. J. Immunol. 158: 2398-2404 [Abstract].
54.	Wells, J.A.. 1994. Structural and functional basis for hormone binding and receptor oligomerization. Curr. Opin. Cell. Biol. 6: 163-173 [Medline].
55.	Pinckard, J.K., K.C. Sheehan, and R.D. Schreiber. 1997. Ligand-induced formation of the p55 and p75 tumor necrosis factor receptor heterocomplexes on intact cells. J. Biol. Chem. 272: 10784-10789 [Abstract/Free Full Text].
56.	Rao, P., K.C. Hsu, and M.V. Chao. 1995. Upregulation of NF- $kappa$ B dependent gene expression mediated by the p75 tumor necrosis factor receptor. J. Interferon Cytokine Res. 15: 171-177 [Medline].
57.	Boldin, M.P., I.L. Mett, E.E. Varfolomeev, I. Chumakov, Y. Shemer-Avni, J.H. Camonis, and D. Wallach. 1995. Self association of the "death domains" of the p55 tumor necrosis factor (TNF) receptor and Fas/APO1 prompts signaling for TNF and Fas/APO1 effects. J. Biol. Chem. 270: 387-391 [Abstract/Free Full Text].
58.	Cheng, G., and D. Baltimore. 1996. TANK, a co-inducer with TRAF2 of TNF- and CD40L-mediated NF- $kappa$ B activation. Genes Dev. 10: 963-973 [Abstract/Free Full Text].
59.	Rabizadeh, S., J. Oh, L.T. Zhong, J. Yang, C.M. Bitler, L.L. Butcher, and D.E. Bredesen. 1993. Induction of apoptosis by the low-affinity NGF receptor. Science. 261: 345-348 [Abstract/Free Full Text].
60.	Haley, J.D., J.J. Hsuan, and M.D. Waterfield. 1989. Analysis of mammalian fibroblast transformation by normal and mutated human EGF receptors. Oncogene. 4: 273-283 [Medline].
61.	Grau, G.E., and D.N. Maennel. 1997. TNF inhibition and sepsis-sounding a cautionary note. Nat. Med. 3: 1193-1195 [Medline].

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Willuweit, A., Sass, G., Schoneberg, A., Eisel, U., Tiegs, G., Clauss, M. (2001). Chronic Inflammation and Protection from Acute Hepatitis in Transgenic Mice Expressing TNF in Endothelial Cells. J. Immunol. 167: 3944-3952 [Abstract] [Full Text]
O'GRADY, N. P., PREAS, H. L. II, PUGIN, J., FIUZA, C., TROPEA, M., REDA, D., BANKS, S. M., SUFFREDINI, A. F. (2001). Local Inflammatory Responses following Bronchial Endotoxin Instillation in Humans. Am. J. Respir. Crit. Care Med. 163: 1591-1598 [Abstract] [Full Text]
Aggarwal, B. B (2000). Tumour necrosis factors receptor associated signalling molecules and their role in activation of apoptosis, JNK and NF-kappa B. Ann Rheum Dis 59: i6-16 [Abstract] [Full Text]
Probert, L., Eugster, H.-P., Akassoglou, K., Bauer, J., Frei, K., Lassmann, H., Fontana, A. (2000). TNFR1 signalling is critical for the development of demyelination and the limitation of T-cell responses during immune-mediated CNS disease. Brain 123: 2005-2019 [Abstract] [Full Text]
Ehlers, S., Kutsch, S., Ehlers, E. M., Benini, J., Pfeffer, K. (2000). Lethal Granuloma Disintegration in Mycobacteria-Infected TNFRp55-/- Mice Is Dependent on T Cells and IL-12. J. Immunol. 165: 483-492 [Abstract] [Full Text]
Ledru, E., Christeff, N., Patey, O., de Truchis, P., Melchior, J.-C., Gougeon, M.-L. (2000). Alteration of tumor necrosis factor-alpha T-cell homeostasis following potent antiretroviral therapy: contribution to the development of human immunodeficiency virus-associated lipodystrophy syndrome. Blood 95: 3191-3198 [Abstract] [Full Text]
Rosenfeld, M. E., Prichard, L., Shiojiri, N., Fausto, N. (2000). Prevention of Hepatic Apoptosis and Embryonic Lethality in RelA/TNFR-1 Double Knockout Mice. Am. J. Pathol. 156: 997-1007 [Abstract] [Full Text]
Minter, R. M., Rectenwald, J. E., Fukuzuka, K., Tannahill, C. L., La Face, D., Tsai, V., Ahmed, I., Hutchins, E., Moyer, R., Copeland, E. M. III, Moldawer, L. L. (2000). TNF-{alpha} Receptor Signaling and IL-10 Gene Therapy Regulate the Innate and Humoral Immune Responses to Recombinant Adenovirus in the Lung. J. Immunol. 164: 443-451 [Abstract] [Full Text]
Skerrett, S. J., Martin, T. R., Chi, E. Y., Peschon, J. J., Mohler, K. M., Wilson, C. B. (1999). Role of the type 1 TNF receptor in lung inflammation after inhalation of endotoxin or Pseudomonas aeruginosa. Am. J. Physiol. Lung Cell. Mol. Physiol. 276: L715-L727 [Abstract] [Full Text]
Fernandez-Real, J.-M., Lainez, B., Vendrell, J., Rigla, M., Castro, A., Penarroja, G., Broch, M., Perez, A., Richart, C., Engel, P., Ricart, W. (2002). Shedding of TNF-alpha receptors, blood pressure, and insulin sensitivity in type 2 diabetes mellitus. Am. J. Physiol. Endocrinol. Metab. 282: E952-E959 [Abstract] [Full Text]

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TABLE OF CONTENTS

A Critical Role of the p75 Tumor Necrosis Factor Receptor (p75TNF-R) in Organ Inflammation Independent of TNF, Lymphotoxin , or the p55TNF-R

Copyright © 1998 by The Rockefeller University Press. 0022-1007/98/10/1343/10 $2.00

A Critical Role of the p75 Tumor Necrosis Factor Receptor (p75TNF-R) in Organ Inflammation Independent of TNF, Lymphotoxin $alpha$ , or the p55TNF-R

Copyright © 1998 by The Rockefeller University Press.
0022-1007/98/10/1343/10 $2.00