Growth/Differentiation Factor-15/Macrophage Inhibitory Cytokine-1 Is a Novel Trophic Factor for Midbrain Dopaminergic Neurons In Vivo

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The Journal of Neuroscience, December 1, 2000, 20(23):8597-8603

Growth/Differentiation Factor-15/Macrophage Inhibitory Cytokine-1 Is a Novel Trophic Factor for Midbrain Dopaminergic Neurons In Vivo
Jens Strelau¹, Aideen Sullivan², Martina Böttner¹, Paul Lingor¹, Elisabeth Falkenstein³, Clemens Suter-Crazzolara¹, Dagmar Galter¹, Jozsef Jaszai¹, Kerstin Krieglstein⁴, and Klaus Unsicker¹
¹ Neuroanatomy and Interdisciplinary Center for Neurosciences, University of Heidelberg, D-69120 Heidelberg, Germany, ² Department of Anatomy, University College, Cork, Ireland, ³ Department of Clinical Pharmacology, Faculty for Clinical Medicine, University of Heidelberg, D-68167 Mannheim, Germany, and ⁴ Department of Anatomy, University of the Saarland, D-66421 Homburg, Germany

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Transforming growth factor- $beta$ s (TGF- $beta$ s) constitute an expanding family of multifunctional cytokines with prominent roles indevelopment, cell proliferation, differentiation, and repair.We have cloned, expressed, and raised antibodies against a distantmember of the TGF- $beta$ s, growth/differentiation factor-15 (GDF-15).GDF-15 is identical to macrophage inhibitory cytokine-1 (MIC-1).GDF-15/MIC-1 mRNA and protein are widely distributed in the developingand adult CNS and peripheral nervous systems, including choroidplexus and CSF. GDF-15/MIC-1 is a potent survival promoting andprotective factor for cultured and iron-intoxicated dopaminergic(DAergic) neurons cultured from the embryonic rat midbrain floor.The trophic effect of GDF-15/MIC-1 was not accompanied by an increasein cell proliferation and astroglial maturation, suggesting thatGDF-15/MIC-1 probably acts directly on neurons. GDF-15/MIC-1 alsoprotects 6-hydroxydopamine (6-OHDA)-lesioned nigrostriatal DAergicneurons in vivo. Unilateral injections of GDF-15/MIC-1 into themedial forebrain bundle just above the substantia nigra (SN) andinto the left ventricle (20 µg each) immediately before a 6-OHDAinjection (8 µg) prevented 6-OHDA-induced rotational behaviorand significantly reduced losses of DAergic neurons in the SN.This protection was evident for at least 1 month. Administrationof 5 µg of GDF-15/MIC-1 in the same paradigm also provided significantneuroprotection. GDF-15/MIC-1 also promoted the serotonergic phenotypeof cultured raphe neurons but did not support survival of ratmotoneurons. Thus, GDF-15/MIC-1 is a novel neurotrophic factorwith prominent effects on DAergic and serotonergic neurons. GDF-15/MIC-1may therefore have a potential for the treatment of Parkinson'sdisease and disorders of the serotonergicsystem.

Key words: GDF-15/MIC-1; TGF- $beta$ ; dopaminergic neurons; 6-OHDA; Parkinson's disease; neurotrophic factor

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Transforming growth factor- $beta$ s (TGF- $beta$ s) are multifunctional, contextually acting cytokines and important regulators of development,cell proliferation, and differentiation (Roberts and Sporn, 1990).The TGF- $beta$ superfamily can be subdivided into several subfamilies,including the bone morphogenetic proteins (BMPs), activins, andglial cell line-derived neurotrophic factor (GDNF)-related proteins(Kingsley, 1994; Hogan, 1996; Unsicker et al., 1999). Severalrepresentatives of these subfamilies are expressed in the centraland peripheral nervous systems (Krieglstein et al., 1995a; Mehlerand Kessler, 1998). Their functions in neural development andmaintenance are only gradually emerging. Several members of theTGF- $beta$ s have been implicated in early morphogenesis of the nervoussystem, dorsoventral patterning, and determination of neural crestcell lineages (Hogan, 1996; Reissmann et al., 1996; Shah et al.,1996). Moreover, TGF- $beta$ s are involved in regulating proliferationof neural progenitor cells (McKinnon et al., 1993; Constam etal., 1994). TGF- $beta$ s have also important roles in the regulationof survival, differentiation, and axonal growth of neurons (Martinouet al., 1990; Ishihara et al., 1994; Krieglstein et al., 1998a;Schober et al., 1999) and orchestrate activities of microglialcells and astrocytes in response to lesions (Finch et al., 1993;Flanders et al., 1998). The neurotrophic potential of TGF- $beta$ s isbest exemplified by the discovery of GDNF (Lin et al., 1993; Saueret al., 1995; Gash et al., 1996; Unsicker et al., 1999), whichsupports survival and differentiation in vitro and in vivo ofdopaminergic (DAergic) neurons of the midbrain that degeneratein Parkinson'sdisease.

We have recently cloned a distant member of the TGF- $beta$ superfamily, GDF-15 (Böttner et al., 1998, 1999). GDF-15 is identicalto macrophage inhibitory cytokine (Bootcov et al., 1997), hence,we suggest to name the molecule GDF-15/MIC-1. In peripheral organsGDF-15/MIC-1 is expressed by epithelial cells in prostate, salivary,and mammary glands, placenta, airway and intestinal epithelia,and kidney proximal tubules and collecting ducts (Böttner etal., 1999). Its functions in these locations are enigmatic. Inmacrophages, MIC-1 is induced by proinflammatory cytokines suchas tumor necrosis factor- $alpha$ , interleukin (IL)-1 $beta$ , and IL-6, butnot by interferon- $gamma$ and lipopolysaccharide (Bootcov et al., 1997).Functionally, MIC-1 may serve in monocytoid cells as an autocrineregulatory molecule, whose expression may be required to limitlater phases of macrophageactivation.

We show now that GDF-15/MIC-1 is widely expressed in the CNS and peripheral nervous system (PNS), most prominently in thechoroid plexus, and is secreted into the CSF. We have expressedthe biologically active molecule in baculovirus and demonstratehere that it is a potent trophic and protective factor for dopaminergicneurons from the embryonic rat midbrain floor and for embryonicraphe serotonergic neurons. Most importantly, GDF-15/MIC-1 normalizesmotor behavior and protects dopaminergic neurons in the substantianigra after unilateral 6-hydroxydopamine lesions, for at least1month.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Expression of recombinant human GDF-15/MIC-1. Full-length GDF-15/MIC-1 cDNA was cloned and sequenced as previously described(Böttner et al., 1998). A PCR product of the mature human GDF-15/MIC-1DNA containing SacII/SphI restriction sites was obtained withtwo specific oligonucleotides (forward primer 5'-ATCCGCGGGCAGAGCGCGTGCGCGCAAC-3'and reverse primer 5'-ATCGTACGTCATATGCAGTGGCAG-3', internal SacIIand SphI sites are underlined). The DNA fragment was subclonedinto the SacII and SphI site of the pBACgus-2cp transfer plasmid(Novagen, Munich, Germany). To confirm the insert in the properreading frame, we subsequently performed sequence analysis ofthe plasmid. Insect Sf9 cells were cotransfected with the recombinanttransfer plasmid and the high-efficiency BacVector-2000 TripleCut Virus DNA according to the manufacturer's instructions (Novagen,Munich, Germany). Together with the GDF-15/MIC-1 DNA a gus genewas inserted into the baculovirus genome, and recombinants producing $beta$ -glucuronidase in infected cells were identified by stainingwith X-Gluc. Positive recombinant virus plaques were picked andpurified by repeated replaquing. A well isolated and purifiedplaque was used to generate a high titer master stock of virus(3 × 10⁹ pfu/ml), which was then used to prepare infected cells for proteinand DNA analyses. Large scale protein production was performedin 10-20 75 cm² T-flasks each with 10 ml of medium containing 10⁶ cells/ml. Sixty hour after infection cells were collected, centrifugedfor 5 min at 500 × g, and the pellet was homogenized in lysisbuffer (1 ml/1 × 10⁸cells) containing 10 mM Tris/HCl, pH 7.5, 150 mM NaCl, 0.1 U/mlaprotinin, and 1 mM PMSF. After centrifugation for 10 min at 15,000× g, the extracted protein was dialyzed against 1× binding buffer(in mM: 5 imidazole, 500 NaCl, and 20 Tris/HCl, pH 7.9). The His-Tagfusion protein was purified from protein extract using His-Bindmetal chelation resin according to the protocol of Novagen (Munich,Germany). Protein extracts of uninfected cells were treated underthe same conditions and used in parallel forcontrols.

In situ hybridization and RT-PCR. The procedure for in situ hybridization has been previously published (Böttner et al.,1999). RT-PCR was used to determine the expression pattern ofGDF-15/MIC-1 in various brain regions and cell cultures of newborn(P0) Sprague Dawley rats. Protocols for dissection, cell culture,total RNA isolation, and first strand cDNA synthesis have beendescribed elsewhere (Jaszai et al., 1998). After reverse transcription,3.5 µl of the cDNA samples were subjected to PCR amplificationusing primers specific for rat GDF-15/MIC-1 (5'-TGCTGAGCCGACTGCATGC-'3and 5'-CATGCTCAGTTGCAGCTGAC-'3). These primers amplify a PCR productof 520 bp. Reactions were performed in a Perkin-Elmer GeneAmpPCR system 9600 thermal cycler in 0.2 ml of thin-walled reactiontubes using "hot-start" method. Reagents were assembled in a finalvolume of 100 µl, and final concentrations of reagents were asfollows: 3.5 µl of first strand cDNA, 1 µM forward primer, 1 µMreverse primer, 1× PCR buffer (10× PCR buffer: 200 mM Tris-HCl,pH 8.4, 500 mM KCl; Life Technologies, Gaithersburg, MD), 2.5mM MgCl₂, 0.1 mM each of dNTPs and RNase-free water to 100 µl.Samples were initially denatured at 94°C for 4 min and 2.5 U ofTaq DNA polymerase, recombinant (Life Technologies) was then added.Thermocycling parameters were then 30 sec denaturation at 94°C,30 sec annealing at 62°C, and 30 sec extension at 72°C repeatedfor 35 cycles with a final extension step at 72°C for 5 min. One-tenthof each PCR reaction was then analyzed by agarose gel electrophoresis.After subcloning the reaction product into pGEM-T (Promega, Mannheim,Germany) PCR cloning vector, the identity of the amplified productwas then further verified bysequencing.

Gel electrophoresis and immunoblot analysis. Protein extracts were prepared from different brain regions and cell culturesof newborn (P0) Sprague Dawley rats. Protocols for dissectionand cell cultures have been described elsewhere (Jaszai et al.,1998). Tissue or cells were homogenized in electrophoresis samplebuffer, and the protein content was determined using a densitometricmethod (Henkel and Bieger, 1994). Equal amounts of 25 µg of proteinextract per lane were loaded on SDS-polyacrylamide gels and transferredto nitrocellulose membranes (Hybond ECL; Amersham Pharmacia, Göttingen,Germany) by electroblotting. The membranes were incubated withpurified polyclonal rabbit anti-rat GDF-15/MIC-1 antibody for16 hr at 4°C. Bound antibody was detected with a peroxidase-conjugatedsecondary antibody and the ECL Western blotting substrate system(Amersham Pharmacia, Göttingen, Germany) in accordance to themanufacturer's manual. Purified recombinant GDF-15/MIC-1 sampleswere visualized with Coomassie blue and quantitated by densitometriccomparison (Henkel and Bieger, 1994) with defined concentrationsof protein standards. Recombinant GDF-15/MIC-1 was analyzed byreducing and nonreducing SDS-PAGE according to standard protocols(Scopes, 1987) and subjected to immunoblotting. Human CSF waskindly provided by Dr. Grau (Neurology, HeidelbergUniversity).

Antibodies and immunocytochemistry. An antibody raised against a specific peptide sequence (HRTDSGVSLQTYDDL) of the C terminusof the GDF-15/MIC-1 protein was raised in rabbit by Dr. J. Pineda(Forschungszentrum Berlin Biotechnik, GmbH, Berlin, Germany).The antibody was separated from antiserum with tosylactivatedpeptide-coated dynabeads M-280 (Dynal, Hamburg, Germany) accordingto the manufacturer's manual. In brief, 1 ml of bead suspension(1.3 × 10⁹ beads/ml) was incubated with 400 µg of peptide in 100 mM PBS,pH 7.4, for 16 hr at 37°C. After inactivation of free tosyl groupswith 0.2 M Tris-HCl, pH 8.5, for 4 hr at 37°C the peptide-coupledbeads were incubated with 0.5 ml of antiserum in 1 ml of PBS for30 min at room temperature. After intensive washing and immunomagneticseparation in a magnet particle concentrator (Dynal), bound antibodywas eluted from the peptide-coupled beads with 0.3 ml of elutionbuffer containing 0.2 M glycine-HCl, pH 2.7, and 0.15 M NaCl for1 min at room temperature. The solution with unbound antibodywas carefully aspirated with an Eppendorf pipette and neutralizedimmediately with 0.1 ml of 0.4 M Na₂HPO₄ containing 0.8% Na-azideand 4 mg/ml BSA. The antibody was stored in a final volume of0.4 ml at 4°C and used in a 1:250 dilution for Western blots.Mesencephalic cell cultures were processed for rat tyrosine hydroxylase(TH; Boehringer Mannheim, Mannheim, Germany), glial fibrillaryacidic protein (GFAP; Sigma, St. Louis, MO) or BrdU (BoehringerMannheim) immunocytochemistry as described earlier (Krieglsteinet al., 1995b). Serotonergic cultures were processed for rat tryptophanhydroxylase (TpOH; Sigma) immunocytochemistry. The method wasas described (Galter and Unsicker, 1999).

Cell culture. Cell cultures from embryonic day 14 (E14) rat midbrain floor were essentially established as described (Krieglsteinet al., 1995b). Cells were seeded at a density of 200,000 percm², cultured under serum-free conditions, and processed for immunocytochemistryon day 7 in vitro (DIV 7). Iron intoxication was performed withFeCl₂ (Fluka, Deisenhofen, Germany) as described (Lingor et al.,1999). Primary raphe cultures from the E14 rat rhombencephalonfloor were prepared as described (Galter and Unsicker, 1999).Cells were seeded at a density of 200,000 per cm², cultured under serum-free conditions and processed for 5,7-dihydroxtryptamine(5,7-DHT) uptake and TpOH immunocytochemistry on DIV 4. Embryonicrat motoneurons (E14) were prepared as described (Goudin et al.,1996; Krieglstein et al., 1998a), using a two-step purificationmethod [metrizamide gradient followed by a panning procedure usingthe monoclonal antibody MC-192 that recognizes the low-affinitynerve growth factor (NGF) receptor]. Embryonic chick (E8) dorsalroot ganglia (DRG) neurons were isolated and grown as described(Krieglstein et al., 1998a). Type 2 astrocytes, O-2A progenitorcells, and oligodendrocytes were obtained from primary corticalglial cultures established from P0 rats, as previously described(Behar et al., 1988). The oligodendroglial progenitor cell lineOLI-neu (Jung et al., 1995) was kindly provided by Dr. J. Trotter(Neurobiology, Heidelberg University, Germany). Growth factorswere from Immunocytochemicals (Ismaning, Germany) (NT-4, GDNF,both human recombinant) and Boehringer Mannheim (NGF, 2.5S).

In vivo studies. Adult female Wistar rats (240-260 gm) were anesthetized using ketamine (75 mg/kg, i.p.) and xylazinum (15mg/kg, i.p.) and placed in a Kopf stereotaxic frame. GDF-15/MIC-1was used at a final concentration of 2 µg/µl in 10 mM PBS, pH7.4. Ten rats received injections of 20 µg of GDF-15/MIC-1 justabove the left substantia nigra (SN) plus 20 µg GDF-15/MIC-1 intothe left lateral ventricle (LV), whereas five additional ratsreceived injections of 5 µg of GDF-15/MIC-1 into each of the samesites. This was followed immediately by an injection of 6-hydroxydopamine(6-OHDA) hydrobromide (8 µg as the free base in 4 µl of 0.9% salinewith 0.1% ascorbic acid) into the left medial forebrain bundle(MFB) of each rat. Ten further rats received sham injections of10 mM PBS into the SN and LV, in addition to a 6-OHDA injection("6-OHDA only" group). Stereotaxic coordinates (Pellegrino etal., 1979) were as follows: anteroposterior (AP) $-$ 3.0, LV +2.5,dorsoventral (DV) $-$ 8.5 for the SN; AP +1.0, LV +1.2, DV $-$ 3.5 forthe LV; AP $-$ 2.2, LV +1.5, DV $-$ 7.9 for theMFB.

All rats were tested behaviorally at 1 week after surgery, and the 1 month group of rats was tested again after a further1 and 2 weeks. Ipsilateral rotations were counted over a 60 minperiod beginning 5 min after (+)-amphetamine sulfate administration(5 mg/kg, i.p.).

At 10 d after surgery, five rats of the 6-OHDA only group, five rats that had received a total dose of 40 µg of GDF-15/MIC-1,and five rats that had received a total dose of 10 µg of GDF-15/MIC-1were killed. They were terminally anesthetized with chloroform/etherand perfused intracardially with 200 ml of cold 0.1 M PBS, pH7.4, containing 500 U of heparin, followed by 300 ml of freshlyprepared 4% paraformaldehyde in PBS. The remaining five rats ofthe 40 µg group and five of the 6-OHDA only group were killedat 1 month after surgery. Five unlesioned control rats were alsokilled at this time. Brains were removed and placed in 4% paraformaldehydein 10 mM PBS overnight, cryoprotected in 30% sucrose in PBS, andthen frozen. Serial 30 µm coronal cryosections through the SNpars compacta (SNpc) were cut and stained immunocytochemicallyfor TH. Sections were incubated in blocking solution (3% normalgoat serum, 0.2% Triton X-100 in PBS) overnight at 4°C, then ina 1:200 solution of mouse antibody to TH (Boehringer Mannheim)in blocking solution overnight at 4°C. Sections were washed fivetimes in PBS containing 0.02% Triton X-100, then incubated ina solution of 1:1000 horseradish peroxidase-linked anti-rabbitIgG (Vector Laboratories, Peterborough, UK) overnight at 4°C.After washing as before, TH immunostaining was visualized using3,3'-diaminobenzidine as the chromogen. Sections were mountedonto gelatinized slides, dehydrated in alcohol, cleared in xylene,and mounted inDePeX.

Unbiased stereological analysis of TH-immunopositive neurons in the left and right SN of each brain was performed using adrawing tube attachment on an Olympus BX40 light microscope. Thevolume of each SN was estimated using the Cavalieri method, whichwas applied to six cryosections per brain (with an intersectiondistance of 200 µm). The number of TH-immunopositive neurons perunit volume was estimated using the Disector method, on threeDisector pairs per brain (pilot studies suggested that three pairswere sufficient for such an estimate). These estimates were usedto calculate the absolute numbers of TH-immunopositive neuronsper left or right SN. ANOVA analysis with post hoc Tukey's testwas used to compare the numbers of surviving TH-immunopositiveneurons in the SN of each treatmentgroup.

Statistics. Data obtained in cell culture experiments were analyzed by a one-way ANOVA, and the significance of intergroupdifferences was determined by applying Student's t test. Differenceswere considered significant at *p < 0.05, **p < 0.01, and ***p< 0.001.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cloning, expression, and distribution of GDF-15/MIC-1 in the nervous system

Members of the TGF- $beta$ superfamily share a distinct spacing of seven conserved cysteine residues within the mature C-terminalportion that form a characteristic cysteine knot motif (McDonaldand Hendrickson, 1993). Using this motif for screening expressedsequence tag (EST) databases resulted in the identification ofseveral identical truncated sequences with the characteristicTGF- $beta$ structure. RT-PCR combined with cDNA library screening revealedthe full-length human, mouse, and rat sequences of a novel memberof the TGF- $beta$ superfamily (Böttner et al., 1998, 1999). We useda His-Tag fusion construct and a baculovirus system for expressingthe mature portion of recombinant human GDF-15/MIC-1 protein inSf9 cells (Fig. 1A-C) and raised antibodies against a C-terminalsynthetic peptide. To demonstrate the specificity of the antibodies,immunoblot analyses with other TGF- $beta$ superfamily members wereperformed. The GDF-15/MIC-1 antibodies revealed no cross-reactivitywith members of the TGF- $beta$ , BMP, or GDNF subfamilies (data notshown). Western blots under reducing conditions showed that recombinantGDF-15/MIC-1 migrates at ~16 kDa (Fig. 1A), i.e., close to thesize of the mature peptide of 12.5 kDa (Bootcov et al., 1997).The difference in the observed bands is probably because of thepresence of the His-Tag in the recombinant protein. Under nonreducingconditions, the expression product migrates as a disulfide-linkeddimer (Fig. 1C). We used these antibodies, RT-PCR, and in situhybridization to reveal regions of expression of GDF-15/MIC-1in the developing and adult brain, in isolated neural cells andperipheral neural tissues (Fig. 2). GDF-15/MIC-1 mRNA and proteincan be detected in many brain areas, including cortex, hippocampus,striatum, pons, and medulla oblongata (Fig. 2C,D). In situ hybridizationrevealed the choroid plexus as a prominent site of synthesis inthe CNS (Fig. 2B). Consistent with this localization of GDF-15/MIC-1mRNA the protein can be detected by immunocytochemistry in theplexus epithelium (data not shown) and by Western blot in theCSF (Fig. 2A). Expression levels of GDF-15/MIC-1 mRNA and proteinin brain areas other than the choroid plexus were too low to bedetected by in situ hybridization and immunocytochemistry, respectively.However, cortical lesions can raise GDF-15/MIC-1 mRNA in selectneuron populations to levels sufficient for visualization by insitu hybridization (M. Böttner, unpublished observations). GDF-15/MIC-1expression is not restricted to the CNS, as shown by the presenceof mRNA and protein in DRG (Fig. 2C,D). RT-PCR and Western blotstudies using isolated neural cells revealed the presence of GDF-15/MIC-1in highly enriched cultured astrocytes, but not in purified O-2Aoligodendroglial progenitor cells and an oligodendroglial cellline, OLI-neu (Fig. 2C,D). Together, these data suggest that GDF-15/MIC-1is widely distributed in the CNS and in the CSF.

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Figure 1. Electrophoretic analysis of recombinant human GDF-15/MIC-1 protein in Sf9 cells. A, Immunoblotting of cell lysate from infected (1) and noninfected (2) insect cells with purified GDF-15/MIC-1 antiserum. The gel was run under reducing conditions. B, Coomassie blue staining of purified recombinant GDF-15/MIC-1 (1) (reducing conditions). C, Immunoblotting of purified recombinant GDF-15/MIC-1 homodimers under nonreducing conditions with purified GDF-15/MIC-1 antiserum (1). MW, Low molecular weight markers.

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Figure 2. Localization of GDF-15/MIC-1 in the CNS. A, Immunoblotting of human CSF with purified GDF-15/MIC-1 antiserum. B, Dark-field image shows in situ hybridization of adult rat choroid plexus with a rat-specific GDF-15/MIC-1 antisense RNA probe. C, RT-PCR of different rat (P0) brain regions (pons, medulla oblongata, cortex, hippocampus, striatum), dorsal root ganglia (drg), cultured primary astrocytes (astr.), the oligodendroglial cell line OLI-neu (OLI), and purified oligodendroglial progenitor cells (O-2A). D, Immunoblotting of rat brain tissues (P0) and cells with purified GDF-15/MIC-1 antiserum. Locations of molecular weight marker bands are provided on the left side of each figure.

GDF-15/MIC-1 promotes survival of cultured and iron-intoxicated midbrain dopaminergic neurons

We next assayed the recombinant purified protein from Sf 9 cells on a variety of cultured CNS and PNS neurons for biologicalactivity and putative neurotrophic effects. As shown in Figure3A-C, GDF-15/MIC-1 is a potent trophic factor for DAergic neuronscultured from the E14 rat midbrain floor. The factor increasesDAergic neuron survival at an optimal concentration (estimated1 ng/ml), twofold above control levels (Fig. 4A). Thus, GDF-15/MIC-1is at least as potent as the best-established dopaminotrophicfactor GDNF (Figs. 3A-C, 4A). Figure 3D-F documents that GDF-15/MIC-1did not increase the number of cells immunoreactive for the astroglialintermediate filament protein GFAP. Moreover, GDF-15/MIC-1 didnot increase numbers of BrdU-incorporating cells (data not shown).This suggests that GDF-15/MIC-1 probably acts directly on neuronsand not through a numerical expansion of cells or stimulationof astroglial cell maturation.

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Figure 3. Photomicrographs of cell cultures established from the E14 rat midbrain floor at DIV 7. Panels show staining with monoclonal antibodies against TH (A, C, E) or GFAP (B, D, F), respectively. Cultures were run as controls (A, B), or treated with GDNF (10 ng/ml; C, D), or GDF-15/MIC-1 (1 ng/ml; E, F). Scale bar, 50 µm.

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Figure 4. In vitro neurotrophic effects of GDF-15/MIC-1. GDF-15/MIC-1 was assayed on rat midbrain DAergic neurons (A, B), rat serotonergic raphe neurons (C), and chick DRG neurons (D). A, Numbers of mesencephalic TH-positive neurons at DIV 7. C, No factors; BC, baculovirus control, i.e., noninfected cells; 1, 2, 3, cultures treated with 0.01, 0.1, and 1 ng/ml GDF-15/MIC-1, respectively; G, GDNF (10 ng/ml). B, Numbers of mesencephalic TH-positive neurons at DIV 8, after intoxication with 100 µM Fe²⁺. C, No factors; NT-4 (10 ng/ml); GDF-15/MIC-1 (1 ng/ml). C, Numbers of TpOH and 5,7 DHT-positive cells at DIV 4 in cultures established from rat E14 raphe. C, Control; 1,2, Cultures treated with 5 (1) or 10 ng/ml (2) GDF-15/MIC-1. D, Numbers of chick (E8) DRG neurons at DIV 2. C, Control, 1, 2, 3, cultures treated with 1, 5, or 10 ng/ml GDF-15/MIC-1; G, cultures treated with GDNF (10 ng/ml); N, cultures treated with NGF (10 ng/ml). Data are given as means ± SEM (n = 3). All experiments were performed in triplicate and repeated at least three times. p values derived from Student's t test are *p < 0.05, **p < 0.01, ***p < 0.001.

Toxins and free radical formation have been implicated in the generation of cell losses in Parkinson's disease (Gerlach andRiederer, 1996). We therefore investigated whether GDF-15/MIC-1was able to protect iron-intoxicated cultured midbrain DAergicneurons from cell death. Figure 4B documents that GDF-15/MIC-1(10 ng/ml) significantly protects DAergic neurons against ironintoxication matching the effect of NT-4 (10 ng/ml), an establishedneuroprotective factor for lesioned DAergic neurons (Lingor etal., 1999). Together, these data indicate that GDF-15/MIC-1 isboth a trophic and neuroprotective factor for midbrain DAergicneurons in vitro.

GDF-15/MIC-1 promotes the serotonergic phenotype of raphe neurons, but does not affect spinal motoneurons

We also assayed GDF-15/MIC-1 on several other CNS and peripheral neuron populations. Figure 4C shows that GDF-15/MIC-1 augmentednumbers of neurons immunoreactive for the 5-HT-synthesizing enzymeTpOH and cells taking up the serotonin analog 5,7-dihydroxytryptamine(5,7-DHT) in cultures established from the E14 rat raphe. GDF-15/MIC-1did not promote the survival of purified rat spinal cord motoneuronsin vitro (data not shown), but had a small, yet significant promotingeffect on chick DRG neurons (Fig. 4D).

GDF-15/MIC-1 protects 6-hydroxydopamine-lesioned nigrostriatal neurons in vivo

The neuroprotective effects of GDF-15/MIC-1 were examined in vivo in adult rats that had received unilateral 6-OHDA-inducedlesions of the nigrostriatal pathway. GDF-15/MIC-1 was administeredjust above the SN and into the LV, a protocol described previouslyfor measuring the effects of GDF-5 and GDNF in this rat model(Sullivan et al., 1997, 1998).

A total dose of 40 µg of GDF-15/MIC-1 completely prevented 6-OHDA-induced rotational asymmetry, indicating that it protectedagainst 6-OHDA-induced depletion of striatal dopamine levels (Table1). This protective effect on rotational behavior was observedfor up to 3 weeks after the lesion. A total dose of 10 µg of GDF-15/MIC-1also induced significant protection (p > 0.0001) against amphetamine-inducedrotations at 1 week after the lesion.


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Table 1. Rotations per minute after amphetamine administration and counts of TH-immunopositive neurons in left and right SNpc

GDF-15/MIC-1 also exhibited potent protective effects on dopaminergic neurons in the SNpc (Table 1, Fig. 5). Both of the6-OHDA only groups exhibited a large loss of TH-immunopositiveneurons in the left SNpc (neurons on left expressed as a percentageof those on right: 6.1 ± 2.0% at 10 d and 5.8 ± 1.3% at 1 month).Both doses of GDF-15/MIC-1 significantly (p < 0.001 for 10 µg;p < 0.0001 for 40 µg) prevented this 6-OHDA-induced loss of dopaminergicneurons in the left SNpc (survival of 51.1 ± 4.0% after 10 µg;67.7 ± 3.6% after 40 µg). Furthermore, this significant sparingof TH-positive neurons was still evident after 1 month in ratstreated with 40 µg of GDF-15/MIC-1 (62.0 ± 3.4%; p < 0.001). Thesparing induced by 40 µg of GDF-15/MIC-1 after 1 month was notsignificantly different from that seen after 1 week, showing thatthe protein induced long-term neuroprotective effects.

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Figure 5. Photomicrographs of cryosections through the left SNpc. Sections were processed for TH immunocytochemistry. Animals were treated as follows: A, vehicle only; B, 6-OHDA only (10 d); C, 6-OHDA plus 10 µg of GDF-15/MIC-1 (10 d); D, 6-OHDA plus 40 µg of GDF-15/MIC-1 (10 d); E, 6-OHDA only (1 month); F, 6-OHDA plus 40 µg of GDF-15/MIC-1 (1 month). Scale bar, 200 µm.

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present data reveal the neurotrophic and neuroprotective potential of a new member of the TGF- $beta$ superfamily in vitro andin vivo. TGF- $beta$ s share a primary structure with six C-terminalcysteines in topologically equivalent positions that form a cysteineknot motif. This structural information was used in an EST databasesearch and resulted in the identification and cloning of the full-lengthcoding sequence of GDF-15 (Böttner et al., 1998, 1999). GDF-15is identical to MIC-1 (Bootcov et al., 1997), which was discoveredindependently, based on its capacity to inhibit lipopolysaccharide-inducedmacrophage activation. Amino acid identity with other membersof the TGF- $beta$ superfamily is 32% and less (Böttner et al., 1999).GDF-15/MIC-1 does not mimic TGF- $beta$ isoforms 1, 2, and 3 in an assayof mink lung epithelial cells (K. Krieglstein and J. Strelau,unpublished observations), suggesting that GDF-15/MIC-1 may notuse the TGF- $beta$ type I and II receptors (Lin et al., 1992).

As shown by RT-PCR and in situ hybridization, GDF-15/MIC-1 mRNA is widely distributed in peripheral organs of rat and mouseincluding the gastrointestinal and respiratory tracts, salivary,mammary, and prostate glands, placenta, kidney, and adrenal glands(Böttner et al., 1999). In situ hybridization shows prominentexpression of GDF-15/MIC-1 mRNA in epithelial cells and macrophages,but not in mesenchyme-derived cells. The present study revealsGDF-15/MIC-1 synthesis in the choroid plexus and its secretioninto CSF, from where a wide range of signaling proteins may reachtarget cells within the brain and spinal cord (Dixon et al., 1997).Many other cytokines with neurotrophic functions, as e.g., fibroblastgrowth factors-1 and -2 (for review, see Bieger and Unsicker,1996), insulin-like growth factors I and II (for review, see Cohickand Clemmons, 1993), and TGF- $beta$ s (for review, see Böttner et al.,2000) show a similarly wide distribution in many peripheral tissuesand in the brain, but are broader than GDF-15/MIC-1 with regardto the spectrum of neuron populations supported (see below). Notonly endogenous, but also exogenously administered molecules,such as neurotrophic factors applied as therapeutic agents againstseveral neurodegenerative diseases, can be distributed withinthe brain by intraventricular and intrathecal routes (Aebischeret al., 1996). RT-PCR and Western blot analyses suggest that GDF-15/MIC-1is also synthesized and stored in CNS tissues other than choroidplexus, as e.g., cortex, hippocampus, striatum, pons, and medullaoblongata. However, mRNA and protein levels in these locationsare apparently too low to be visualized by in situ hybridizationand immunocytochemistry. Western blots of brain homogenates andlysates of cultured cells reveal one immunoreactive band migratingat ~30 kDa. This corresponds to the calculated size of the pro-protein.Because the antibodies used also recognize the mature form ofGDF-15/MIC-1, as demonstrated with the recombinant (Fig. 1A; calculatedMW ~14.5 kDa) and CSF-derived protein (Fig. 2A; ~12.5), we assumethat levels of mature GDF-15/MIC-1 in tissue and cell lysatesmay be below detection limit. This assumption is supported bythe previous demonstration that intracellular MIC-1 exists predominantlyin its pro-form (Bootcov et al., 1997).

Synthesis of GDF-15/MIC-1 by choroid plexus epithelial cells is reminiscent of TGF- $beta$ 1, which is also strongly expressed inthe choroid plexus, but hardly detectable in brain parenchyma(Flanders et al., 1989). Like GDF-15/MIC-1, TGF- $beta$ 1 is secretedinto the CSF (Huang et al., 1997) and acts as a trophic factoron several classes of CNS neurons (Krieglstein et al., 1995a).

The capacity of GDF-15/MIC-1 to promote survival and phenotypical development of mesencephalic DAergic and raphe serotonergicneurons denotes the first known functions of this molecule inthe nervous system. The neurotrophic effects were seen on bothunlesioned and toxically impaired DAergic neurons both in vitroand in vivo. A growing body of evidence suggests that increasedformation of toxic radicals as well as decreased radical scavengeractivities (Ruberg et al., 1997) may play major roles in neuronaldeath. Iron catalyzes, by means of the fenton reaction, the productionof the HO radical from hydrogen peroxide (H₂O₂). Elevated levelsof iron have been found in postmortem sections of patients withParkinson's disease (Hirsch et al., 1991; Sofic et al., 1991).Our data indicate that GDF-15/MIC-1 can protect against iron-mediatedcytotoxicity as efficiently as neurotrophin-4. This, togetherwith the observation that GDF-15/MIC-1 is at least as potent asGDNF in promoting the survival of DAergic neurons makes this moleculeattractive for assessing its potency in the treatment of humanParkinson's disease. The significance of GDF-15/MIC-1 for promotingsurvival of midbrain DAergic neurons is further underscored bythe fact that its neurotrophic effects are not mediated by astroglialcells. Both control and treated cultures contained <0.2% GFAP-positivecells (Hyman et al., 1991), and their numbers did not increasein response to GDF-15/MIC-1. In contrast, the dopaminotrophiceffects of several growth factors including BMPs, FGF-2, EGF,TGF- $alpha$ , IGF-I, and IGF-II (Casper et al., 1991; Engele and Bohn,1991; Alexi and Hefti, 1993; Jordan et al., 1997) are accompaniedby a massive increase in cell number. Their effects are abolishedby inhibition of cell proliferation and astroglial maturationarguing against a therapeutic potential of thesefactors.

Most importantly, GDF-15/MIC-1 effectively protects the adult rat nigrostriatal pathway against a complete lesion inducedby 6-OHDA. GDF-15/MIC-1 preserved both striatal nerve terminals,as shown by the absence of amphetamine-induced rotational behavior,and dopaminergic cell bodies in the SNpc, as seen in the immunocytochemicalstudy. It is promising that the neuroprotective effects of GDF-15/MIC-1are still evident after 1 month. The neuroprotective effects ofGDF-15/MIC-1 compare well with those previously observed withGDNF and GDF-5 in this rat model of Parkinson's disease (Sullivanet al., 1997, 1998). In the present study, a dose of 40 µg ofGDF-15/MIC-1 induced sparing of 67.7% of dopaminergic neuronsafter 10 d and of 62.0% after 1 month. Following the same administrationprotocol as that used in the present study, a total dose of 75µg of GDNF induced 77.5% survival of dopaminergic neurons, whereas50 µg of GDF-5 spared 65.0%. Because the failure of the recentclinical trial of GDNF in a Parkinsonian patient (Kordower etal., 1999), the search for effective dopaminergic neurotrophicfactors remains. The present data suggest that GDF-15/MIC-1 mayhave the potential to be of therapeutic benefit in Parkinson'sdisease.

With regard to the spectrum of responsive neuron populations, the present data suggest that GDF-15/MIC-1 may preferentiallyaddress DAergic and serotonergic neurons, making it an interestingfactor for potential applications in the treatment of Parkinson'sdisease and disorders of the serotonergic system. In terms ofbiological responses GDF-15/MIC-1 is distinct from GDNF, whichaddresses a wider spectrum of CNS and PNS neurons (Unsicker etal., 1999). With TGF- $beta$ 1/2/3, GDF-15/MIC-1 shares CNS aminergicneurons as targets (Krieglstein et al., 1994, 1995a; Galter andUnsicker, 1999), but is distinct in that it does not address spinalcord motoneurons (Goudin et al., 1996; Krieglstein et al., 1998a).

In conclusion, the present data indicate that GDF-15/MIC-1, a novel member of the TGF- $beta$ superfamily, is a potent neurotrophicfactor for developing and lesioned aminergic neurons in vitroand in vivo, with a potency matching that ofGDNF.

  FOOTNOTES

Received July 17, 2000; revised Sept. 5, 2000; accepted Sept. 11, 2000.

This work was supported by grants from Deutsche Forschungsgemeinschaft and Bundesministerium für Bildung und Forschung. Wethank Jutta Fey, Anne Heinke, Marion Schmidt, and Ulla Hinz forexcellent technicalassistance.
Correspondence should be addressed to Klaus Unsicker, Neuroanatomy and Interdisciplinary Center for Neurosciences, Universityof Heidelberg, Im Neuenheimer Feld 307, 2 OG, D-69120 Heidelberg,Germany. E-mail: klaus.unsicker{at}urz.uni-heidelberg.de.

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