The Molecular Mechanism of B Cell Activation by toll-like Receptor Protein RP-105

doi:10.1084/jem.188.1.93

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J. Exp. Med., Volume 188, Number 1, July 1, 1998 93-101

The Molecular Mechanism of B Cell Activation by toll-like Receptor Protein RP-105

By Vivien W.F. Chan,^* Ingrid Mecklenbräuker,^§ I-hsin Su,^§ Gemma Texido,^§ Michael Leitges, Rita Carsetti, Clifford A. Lowell,^* Klaus Rajewsky,^§ Kensuke Miyake,^¶ and Alexander Tarakhovsky^§

From the ^* Department of Laboratory Medicine, University of California, San Francisco, California 94143; Laboratory of Lymphocyte Signaling and ^§ Department of Immunology, Institute for Genetics, University of Köln, Weyertal 121, D-50931 Köln, Germany; Max-Planck-Institut für Immunbiologie, Stubeweg 51, D-79108 Freiburg, Germany; and ^¶ Department of Immunology, Saga Medical School, Nabeshima, Saga 849, Japan

Abstract

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The B cell-specific transmembrane protein RP-105 belongs to the family of Drosophila toll-like proteins which are likely totrigger innate immune responses in mice and man. Here we demonstratethat the Src-family protein tyrosine kinase Lyn, protein kinaseC $beta$ I/II (PKC $beta$ I/II), and Erk2-specific mitogen-activated protein(MAP) kinase kinase (MEK) are essential and probably functionallyconnected elements of the RP-105-mediated signaling cascade inB cells. We also find that negative regulation of RP-105-mediatedactivation of MAP kinases by membrane immunoglobulin may accountfor the phenomenon of antigen receptor-mediated arrest of RP-105-mediatedB cell proliferation.

Key words: RP-105; B lymphocytes; signal transduction; mice

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

Activation of B cells during adaptive immune responses requires coordinated signaling through the surface expressed antigenreceptor and coreceptors such as CD19, CD21, or CD22 (1). Thecombined antigen receptor- and coreceptor-derived signals definethe degree of B cell activation and the strength of humoral immuneresponses (2). In contrast to adaptive immune responses, innateimmune responses are antigen receptor-independent and inducedby invariant molecular structures in pathogens (pathogen-associatedmolecular pattern, PAMPs)¹ via pattern-recognition receptors (PRRs; reference 3). Thecommon feature of B cell-activating PAMPs such as bacteria cellwall lipopolysaccharide (4), viral hemagglutinins (5, 6),or CpG-rich bacterial DNA (7) lies in their ability to inducepolyclonal B cell activation as defined by strong proliferativeresponses associated with upregulation of the surface expressedMHC class II and costimulatory receptor molecules CD80 (B7.1)and CD86 (B7.2) (8).

Responses of this type were found recently to be mediated by a human homologue of the Drosophila toll protein (9). Theexpression of a constitutively active form of human toll in amonocytic cell line leads to induction of expression of inflammatorycytokines such as IL-1, IL-8, IL-6, IFN- $gamma$ , as well as to the expressionof the costimulatory molecule CD80 (9). Human toll belongsto the family of leucine-rich PRRs which also comprises the LPSreceptor CD14 (10) and the toll-like protein RP-105 (11).RP-105 is a 105-kD transmembrane protein expressed on the surfaceof mature B cells in mice (12) and B lymphocytes and dendriticcells in humans (13, 14). As in toll protein, the extracellulardomain of RP-105 is characterized by the presence of multipletandemly repeated leucine-rich motifs separated from the singletransmembrane domain by a carboxy-flanking region (11). Thesimilarity between toll and RP-105 is further strengthened bythe presence of conserved cysteine residues in the carboxy-flankingregion of toll and RP-105 (11). These cysteine residues areessential for the regulation of signal transduction through toll(9) and, possibly, RP-105.

Antibody-mediated cross-linking of RP-105 in vitro induces a strong proliferative response in B cells that can be inhibitedby surface IgM (sIgM) cross-linking (15). Thus, the simultaneoustreatment of B cells with anti-RP-105 and anti-IgM or incubationof anti-RP-105-induced B cell blasts with anti-IgM leads to cellgrowth arrest and apoptotic death (15). The described signalingproperties of RP-105 suggest a possible role of this protein inregulation of B cell activation during immune responses and invitequestions about the mechanisms of RP-105-mediated signal transduction.Using a combination of biochemical and genetic approaches we analyzedthe mechanism of RP-105- mediated signaling. Our data demonstratethat the Src-family protein tyrosine kinase Lyn, protein kinaseC $beta$ I/II (PKC $beta$ I/II) and Erk2-specific mitogen-activated protein(MAP) kinase kinase MEK are essential and probably functionallyconnected elements of the RP-105-mediated signaling cascade. Wealso find that negative regulation of anti-RP-105-induced activationof MAP kinases by membrane immunoglobulin may account for thearrest of RP-105- induced proliferation mediated by the antigenreceptor.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Mice.

The lyn^-/-, fyn^-/-, and PKC $beta$ I/II^-/- mice were described previously (16). Lyn^-/- mice that had developed splenomegaly were not used. The Blk^-/- mice were generated by using ES cells in which exon 8, encodingthe tyrosine kinase domain of Blk was replaced by neo^r gene (Texido, G., manuscript in preparation). The B cells expressingthe dominant negative mutant of MEK (dnMEK) were derived in vivofrom chimeric RAG-2-deficient mice, in which the lymphoid systemwas reconstituted with the ES cells carrying multiple copies ofthe dnMEK transgene under the control of B cell-specific regulatoryelements (Carsetti, R., A. Tarakhovsky, manuscript in preparation).

Cells and Antibodies.

Unless otherwise indicated tissue culture media used was RPMI 1640 supplemented with 5% FCS, 2 mM pyruvate, 2 mM glutamine,and 50 µM $beta$ -mercaptoethanol. Splenic B lymphocytes were purifiedas described (16, 18). Goat or rabbit anti-mouse IgM (JacksonImmunoResearch Laboratories, West Grove, PA) was used for theinduction of sIgM-mediated protein tyrosine phosphorylation andCa²⁺ mobilization in B cells. AffiPure goat anti-mouse IgM (2.5 µg/ml;Dianova, Hamburg, Germany), IL-4 (25 U/ml; Genzyme Corp., Boston,MA) and monoclonal anti-RP-105 antibody (12) were used for theactivation of B cells in vitro. Anti-Lyn and anti-Syk polyclonalantisera were generated and used as described (19, 20). Rabbitanti-Shc was a gift from Dr. Mary Crowley (Scripps Institute,La Jolla, CA). Anti-phosphotyrosine mAb-4G10 was from UpstateBiotechnology Inc. (Lake Placid, NY). Polyclonal anti-Vav, anti-Erk2,anti-JNK1/anti-JNK-2, and anti-p38 antibodies were obtained fromSanta Cruz Biotechnology (Santa Cruz, CA). Culture supernatantof anti-Fc $gamma$ RII-III (mAb2.4G2) was obtained from cells from AmericanType Culture Collection (ATCC, Rockville, MD).

Analysis of B Cell Proliferation and Upregulation of Activation Markers.

Purified splenic B cells (5 × 10⁶/ml) were cultured for 24 h in 24-well flat-bottom plates in media supplemented with 10% FCSin the absence or presence of anti-RP-105. After incubation, cellswere stained with phycoerythrin-conjugated antibodies to B220/CD45R(RA3-6B2), fluorescein-conjugated antibodies to B7.2 (CD86; PharMingen,San Diego, CA), or MHC class II (M5/114) and analyzed by two-colorflow cytometry on a FACScan^® (Becton Dickinson & Co., Sparks, MD). For dose- dependent proliferativeresponse, purified splenic B cells were cultured at 2 × 10⁵/well or at 4 × 10⁵/well in 96-well flat-bottom plates for 36 h followed by the additionof [³H]thymidine (1 µCi/well) for the next 8 h. The cells were harvestedon filters and the incorporation of [³H]thymidine in cell DNA was measured as described (18).

In Vitro Kinase Assays.

After stimulation with anti-IgM or anti-RP-105, the B cells were lysed and Erk2, JNK1/2 or p38 MAP kinase isoforms were immunoprecipitatedfrom B cell lysates by corresponding polyclonal antibodies (16).Assessment of MAP kinase isoform activity was carried out as described(21). The phosphorylation of substrates was quantified by PhosphorImageranalysis. After analysis the membranes were reprobed with antibodiesto each respective kinase to confirm equivalent immunoprecipitationin each sample. Lyn immunoprecipitation, immunoblot analysis anddetermination of Lyn protein kinase activity were carried outas described (22). Immunoprecipitates were washed with kinasebuffer (20 mM Tris, pH7.2, 10 mM MgCl₂, 10 mM MnCl₂, 0.1% NP-40)and resuspended in 50 µl of the same buffer containing 0.5 µgof acid-denatured rabbit muscle enolase (Sigma Chemical Co., St.Louis, MO) and 10 µCi of $gamma$ -[³²P]ATP. The phosphorylation reaction was performed at room temperatureand stopped by addition of Laemmli buffer. Aliquots of the reactionmix were separated on 10% PAGE, transferred to nitrocellulosemembrane and Lyn-mediated enolase phosphorylation was quantitatedby PhosphorImager analysis.

Flow Cytometry and Calcium Mobilization.

FACS^® analysis was performed on a FACScan^® (Becton Dickinson & Co.) and the data were analyzed using CellQuest v3.1 software(Beckton Dickinson & Co.). The analysis of Ca²⁺ mobilization was carried out as described (21). In some experiments,Fc $gamma$ receptors (Fc $gamma$ R) on B cells were blocked by preincubationof splenocytes with the anti-Fc $gamma$ RII-III mAb 2.4G2. The stainedcells were washed and resuspended in media/Hepes. After establishingbase line fluorescence in the FITC (530 nm) channel, cells werestimulated by addition of anti-IgM or anti-RP-105 and data werecollected continuously over a 14-min interval. Results were plottedas the mean Fluo-3 fluorescence at 20-s intervals.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Early Signaling Events Induced by Anti-RP-105 Antibodies.

Incubation of purified splenic B cells with anti-RP-105 antibody leads to the activation of B cells as determined by the upregulationof surface MHC class II (Fig. 1, top), the costimulatory moleculeB7.2 (Fig. 1, middle) and a strong dose-dependent proliferativeresponse (Fig. 1, bottom). The possible mechanisms of RP-105-mediatedB cell activation were addressed by analyzing RP-105-mediatedprotein tyrosine phosphorylation and Ca²⁺ mobilization. Both of these events are known to precede ligand-inducedupregulation of costimulatory molecules and proliferation of Bcells (23, 24).

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Fig. 1. RP-105-mediated activation of splenic B cells in vitro. Splenic B cells were purified and stimulated as described in Materials and Methods. Histograms show the surface expression levels of MHC class II (top) or costimulatory molecule CD86 (middle) on B cells incubated for 24 h in the absence (thin line) or presence of anti-RP-105 antibody (5 µg/ml) (bold line). For the analysis of anti-RP-105-mediated proliferation, purified splenic B cells were cultured either at 2 × 10⁵/well (circles) or at 4 × 10⁵/well (squares) with the indicated amounts of anti-RP-105 for 36 h. [³H]thymidine (1 µCi/well) was added 8 h before cell harvesting. The proliferation of B cells was determined by the analysis of the amount of [³H]thymidine incorporated into the DNA of stimulated cells.

In contrast to the strong induction of protein tyrosine phosphorylation in anti-IgM-stimulated cells, the treatment of B cellswith anti-RP-105 at the concentration optimal for B cell proliferation(5 µg/ml) results in a very modest increase in tyrosine phosphorylationof proteins with molecular masses ranging from 60 to 95 kD (Fig.2 a). Moreover, proteins such as Syk, Vav, or Shc, which serveas common substrates for various receptor-linked protein tyrosinekinases (PTKs; reference 23), do not undergo any major changein degree of phosphorylation upon RP-105 cross-linking in comparisonto the changes seen after treatment with anti-IgM (Fig. 2 b anddata not shown).

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Fig. 2. Induction of protein tyrosine phosphorylation by anti-RP-105. Purified wild-type splenic B cells were stimulated with goat anti-IgM (10 µg/ml) or anti-RP-105 (5 µg/ml) for the indicated periods of time and cell lysates were prepared. (a) Whole cell lysates (15 µg of protein) were resolved on 10% SDS-PAGE, transferred to nitrocellulose membranes and phosphorylation of the transferred proteins was determined by incubation of membranes with anti-phosphotyrosine antibody 4G10. The two predominant bands seen in all samples at molecular masses ~55 kD represent p53/p56^lyn. Equal protein loading was verified by reprobing the blots with the anti-Syk antibody. (b and c) Whole cell lysates were immunoprecipitated with anti-Syk antibody, the immunoprecipitates were resolved on 10% PAGE and the amount (b) and phosphorylation (c) of the immunoprecipitated Syk was analyzed by immunoblotting with 4G10 mAb. Two protein bands on c reflect a difference in the phosphorylation of Syk.

Activation of B cells by various agonists such as anti-IgM, CD40 ligand, or anti-CD38 is accompanied by Ca²⁺ mobilization from intracellular stores (25). In sharp contrastto the rapid rise in cytosolic Ca²⁺ concentration induced by anti-IgM, the incubation of B cellswith anti-RP-105 causes a very slow and gradual increase in cytosolicCa²⁺ concentration (Fig. 3 a). Although blockade of Fc $gamma$ R dramaticallyincreases the duration of anti-IgM-induced Ca²⁺ mobilization, this treatment has essentially no effect on anti-RP-105-induced Ca²⁺ mobilization (Fig. 3 a). These data indicate that the Fc $gamma$ R doesnot regulate anti-RP-105-induced Ca²⁺ mobilization. The role of Ca²⁺ in RP-105-mediated B cell activation was further addressed byanalyzing the effect of cyclosporin A (CsA) on anti-RP-105-inducedproliferation. This drug inhibits the Ca²⁺-dependent phosphatase calcineurin which controls the phosphorylationand, therefore, nuclear translocation of transcription factorNF-AT in lymphocytes (28, 29). Despite the striking differencesin kinetics and amplitude of Ca²⁺ mobilization induced by anti-RP-105 and anti-IgM, the anti-RP-105-inducedproliferation of B cells is inhibited by CsA with the same efficiencyas the proliferation of B cells induced by anti-IgM in combinationwith IL-4 (Fig. 3 c). These data suggest that Ca²⁺-dependent calcineurin activation plays an essential role in theinduction of B cell proliferation by anti-RP-105.

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Fig. 3. Ca²⁺ mobilization is essential for anti-RP-105-induced B cell proliferation. (a) Purified splenic B cells were stimulated with rabbit anti-IgM (10 µg/ml) or anti-RP-105 (5 µg/ml) (either with or without prior blocking of Fc $gamma$ R with anti-Fc $gamma$ RII-III-mAb). Mobilization of intracellular Ca²⁺ was analyzed by flow cytometry as described in Materials and Methods. Antibodies were added at the time points indicated by the arrow. Closed symbols represent cells stimulated with rabbit anti-IgM (diamonds and triangles, with or without prior blocking of Fc $gamma$ R, respectively); open symbols represent stimulation with anti-RP-105 (circles and squares, with or without prior blocking of Fc $gamma$ R, respectively). (b) Splenic B cells were stimulated with anti-IgM (10 µg/ml), anti-RP-105 (5 µg/ml) or anti-IgM in combination with anti-RP-105 (at the concentrations mentioned above) and calcium mobilization was analyzed. Closed triangles represent stimulation with anti-IgM alone, open circles represent stimulation with anti-RP-105 alone, and open squares with crosses represent stimulation with both anti-IgM and anti-RP-105. (c) Inhibition of the RP-105-induced B cell proliferation by cyclosporin A (CsA). B cells (5 × 10⁵/well) were stimulated with anti-IgM (2.5 µg/ml) and IL-4 (25 U/ml; squares) or with anti-RP-105 (5 µg/ml) (circles) in the presence or absence of the indicated concentrations of CsA for 36 h. Cyclosporin A (Sigma Chemical Co.) was dissolved at 2.5 mg/ml in ethanol and then further diluted in culture medium. Each symbol shows the degree of inhibition (%) of [³H]thymidine incorporation into the DNA of stimulated purified splenic B cells in the presence of CsA. Representative result from one of three independent experiments is shown. The triplicate values for proliferation were as follows: unstimulated B cells 2,978 ± 126; B cells stimulated with: anti-IgM plus IL-4 5,625 ± 583; anti-RP-105 26,537 ± 2,203 cpm.

Engagement of various surface-expressed B cell receptors such as the antigen receptor, the CD19/CD21 complex, CD22, or CD40leads to the activation of MAP kinases ERK2, SAPK/JNK, and p38(1, 30). Treatment of B cells with anti-RP-105 results ina dose-dependent activation of these MAP kinase isoforms (Fig.4, a-c, lanes 1, 3-5). Activation of Erk2 and p38 reaches a maximumwithin 15 min of RP-105 treatment and diminishes at 45 min, whereasJNK1/2 shows sustained activation (Fig. 5, a-c, left). Averagedover multiple experiments, activation of MAPK isoforms was muchstronger after anti-RP-105 treatment than after anti-IgM stimulation(Table 1). However, the kinetics of activation of MAPK isoformsby anti-RP-105 is slower as compared with the previously reportedanti-IgM- induced MAPK activation (16). Although anti-IgM treatmentof B cells leads to maximal induction of Erk2 activity within3-5 min, the maximal Erk2 activation by anti-RP-105 requires ~15min (Fig. 5, a-c, left).

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Fig. 4. The dose-dependent activation of MAP kinase isoform by RP-105 and anti-IgM-mediated negative regulation of RP-105-mediated MAPK activation. Purified splenic B cells from wild-type C57BL/6 and lyn^/ mutant mice (4 × 10⁶ cells/ml of media) were stimulated for 15 min with anti-IgM, anti-RP-105 at the indicated concentrations or with the combination of both. The cell lysates (50 µg of protein) were immunoprecipitated with anti-Erk2 (a), anti-JNK1/2 (b), or anti-p38 (c), and the immunoprecipitates were used for in vitro kinase assays (see Materials and Methods). Phosphorylated substrates were resolved on a 10% PAGE and quantitated by PhosphorImager analysis. The n-fold activation was determined relative to the levels of MAP kinase activity in unstimulated cells.

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Fig. 5. The kinetics of RP-105-mediated activation of MAPK isoforms in wild-type and lyn^/ B cells. Purified splenic B cells from wild type C57BL/6 and lyn^/ mice (4 × 10⁶ cells/ml of media) were stimulated with anti-IgM (10 µg/ml) or anti-RP-105 (5 µg/ml) for the indicated periods of time and cell lysates were prepared. Immunoprecipitations and determination of Erk2 (a), JNK1/2 (b), and p38 (c) kinase activities were carried out as described for Fig. 4.

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Table 1
Activation of MAPK Isoforms in Wild-type and lyn^/ B Cells

The Essential Roles of Lyn, PKC $beta$ I/II, and MAP Kinase Kinase in Anti-RP-105-induced B Cell Proliferation.

The low level of anti-RP-105-induced protein tyrosine phosphorylation does not exclude the involvement of PTKs in RP-105-mediatedsignaling. Indeed, the dramatic reduction of anti-RP-105-inducedproliferation of xid B cells demonstrates the essential role ofprotein tyrosine kinase Btk in RP-105-mediated signaling (12).The activation of Btk is partially regulated by Src-family PTKs(31, 32). In B cells the Src-family kinases are representedmostly by Blk, Fyn and Lyn (33). The role of Src-family PTKsin RP-105- mediated signaling was addressed by analyzing anti-RP-105-inducedactivation of B cells deficient for Blk, Fyn, or Lyn. RP-105-inducedproliferation is unaltered in Blk- and Fyn-deficient B cells (Fig.6). In sharp contrast to Blk- and Fyn-deficient B cells, the proliferativeresponses of Lyn-deficient B cells are dramatically reduced ascompared with responses of the wild-type (Fig. 6). The surfaceexpression levels of RP-105 in Lyn-deficient B cells are similarto those in wild-type B cells (data not shown), excluding thatreduction of RP-105 signaling is due to the downregulation ofRP-105 expression in the absence of Lyn.

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Fig. 6. Proliferative responses of blk^/, fyn^/, lyn^/, PKC $beta$ I/ II^/, and dnMEK B cells to anti-RP-105. Splenic B cells isolated from wild-type control mice (open symbols) or mutant mice (filled symbols) were cultured in the absence (triangles) or presence (circles) of anti-RP-105 (5 µg/ml). Each symbol represents the mean value of triplicate measurements in individual experiments. For the analysis of blk^/, PKC $beta$ I/II^/, and dnMEK, 129/Sv mice-derived B cells were used as a control. The C57BL/6 mice-derived B cells were used as a control for the analysis of responses of lyn^/ B lymphocytes.

In view of the essential role of Lyn in RP-105-mediated B cell proliferation, the activation of Lyn by anti-RP-105 was analyzedby a sensitive immunocomplex kinase assay (22). Incubation ofwild-type B cells with anti-RP-105 or anti-IgM results in increaseof protein tyrosine kinase activity of Lyn as determined by phosphorylationof the exogenous substrate enolase and increase of Lyn autophosphorylation(Fig. 7 a). The kinase activity of Lyn in anti-IgM-treated B cellsreaches the maximum after 1 min and declines to the basal levelof activity after 15 min of incubation (Fig. 7 a). In contrast,the activation of Lyn by RP-105, although not as high as in anti-IgM-treatedcells, remains constant for 30 min at least (Fig. 7). Notably,the amounts of immunoreactive Lyn did not vary between the samples(Fig. 7 b).

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Fig. 7. Anti-RP-105-induced activation of Lyn kinase. Purified splenic B cells from wild-type C57BL/6 mice were treated with either goat anti-IgM (10 µg/ml) or anti-RP-105 (5 µg/ml) for the indicated periods of time. 50 µg of lysate protein were used for anti-Lyn immunoprecipitation/immune complex kinase assay with enolase added as an exogenous substrate (see Materials and Methods). (a) The products of the in vitro kinase reactions were resolved on a 10% PAGE and relative phosphorylation of enolase (normalized to unstimulated cells) was quantitated by PhosphorImager analysis. (b) The amount of Lyn in whole cell lysates (15 µg) was determined by immunoblot analysis with anti-Lyn antibody.

The defect of anti-RP-105-induced activation of Lyn-deficient B cells and the previously described impairment of anti-RP-105-inducedproliferation of xid B cells (12) suggest a functional linkbetween Lyn and Btk within the RP-105-dependent signaling cascade.In B lymphocytes and mast cells Btk appears to be associated withprotein kinase C $beta$ I/II (PKC $beta$ I/II) (36). The physiological importanceof Btk-PKC $beta$ I/II interaction in B cell function is underscoredby the demonstration of essentially identical profiles of B cellsignaling defects in PKC $beta$ I/II-deficient and xid B cells (18).To determine whether PKC $beta$ I/II plays a role in RP-105-mediatedB cell activation, the anti-RP-105-induced proliferation of PKC $beta$ I/II-deficientB cells was analyzed. The PKC $beta$ I/II-deficient B cells express RP-105at levels similar to those in control B lymphocytes (data notshown). Similar to xid B cells, which do not proliferate in responseto anti-RP-105 (12), treatment of PKC $beta$ I/II-deficient B cellswith anti-RP-105 does not induce detectable proliferative responses(Fig. 6).

Activation of MAP kinase isoforms by anti-RP-105 and impaired RP-105-mediated activation of Lyn-deficient, xid, or PKC $beta$ I/II-deficientB cells suggests a link between the Lyn-Btk/PKC $beta$ I/II signalingchain and MAP kinases in the RP-105-dependent signaling cascade.Indeed, the treatment of Lyn-deficient B cells with anti-RP-105is accompanied by a significantly weaker activation of MAP kinaseisoforms as compared with wild-type B cells (Fig. 5 and Table1). A similar result was obtained by the analysis of anti-RP-105-inducedMAP kinase activation in xid B cells (data not shown). The roleof MAP kinases in anti-RP-105-induced B cell activation was furtheraddressed by the analysis of anti-RP-105-induced proliferationof splenic B cells expressing the dominant-negative form of MAPkinase kinase (MEK; Carsetti, R., and A. Tarakhovsky, manuscriptin preparation). B cells expressing the dominant negative mutantof MEK (dnMEK) were derived in vivo from chimeric RAG-2-deficientmice in which the lymphoid system was reconstituted by ES cellscarrying multiple copies of the dnMEK transgene under the controlof B cell-specific regulatory elements (Carsetti, R., and A. Tarakhovsky,manuscript in preparation). Expression of dnMEK in B cells suppressesthe activation of MAP kinase by stimuli such as anti-IgM or phorbolester in combination with ionomycin (Carsetti, R., and A. Tarakhovsky,manuscript in preparation). Incubation of dnMEK-expressing B cellswith anti-RP-105 antibody at a concentration inducing strong proliferationof wild-type control B cells does not induce the proliferationof transgenic B cells (Fig. 6).

Counterregulation by sIgM of RP-105-mediated MAP Kinase Activation and Calcium Mobilization.

In spite of the strong proliferation-inducing potential of anti-RP-105, the simultaneous antibody-mediated ligation of sIgMand RP-105 in vitro leads to B cell growth arrest and death (15).The degree of MAP kinase activation and/or changes in the patternof activated MAPK isoforms induced by engagement of various receptormolecules define the fate of responding cells (37). To determinewhether the negative regulation of RP-105 signaling by sIgM couldbe detected at the level of MAP kinase isoform activation, purifiedsplenic B cells were incubated with variable amounts of anti-RP-105in the presence or absence of anti-IgM. Antibody-mediated cross-linkingof RP-105 results in a dose-dependent increase of the activitiesof Erk2, JNK1/2, and p38 (Fig. 4). The level of MAP kinase isoformactivation by anti-RP-105 at a concentration optimal for B cellproliferation (5 µg/ml) is significantly higher than that inducedby anti-IgM. However, simultaneous incubation of B cells withanti-RP-105 and anti-IgM reduces the amplitude of MAP kinase isoformactivation to levels characteristic for anti-IgM-induced MAP kinaseactivation alone (Fig. 4). The dominance of antigen receptor-mediatedsignaling is similarly observed in lyn^/ B cells, where low levels of anti-RP-105-induced MAPK activationbecome significantly higher upon costimulation with anti-IgM (Fig.4).

The negative regulation of RP-105 signals by signals through the antigen receptor were also seen at the level of Ca²⁺ mobilization. Coincubation of B cells with anti-IgM and RP-105induced a Ca²⁺ mobilization response that is indistinguishable from Ca²⁺ mobilization in cells treated with anti-IgM alone (Fig. 3 b).

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

This study advances the understanding of two questions regarding the activation of B cells by RP-105. First, can a biochemicalpathway of RP-105-mediated intracellular signaling be identified?Second, what is the mechanism of negative regulation of RP-105-mediatedB cell activation by the antigen receptor? Using genetic and biochemicalapproaches we revealed a critical role of Lyn in RP-105- mediatedB cell activation. Lyn is one of the most abundant Src-familyPTKs in B cells and is known to be associated with the antigenreceptor and the CD19 coreceptor (38, 39). Although an associationof Lyn with RP-105 has not been detected (Miyake, K., unpublishedobservation), the rapid though modest increase of kinase activityof Lyn upon anti-RP-105 treatment suggests a proximal locationof Lyn with regard to the putative RP-105 signaling complex. Theactivation of Lyn kinase by RP-105 does not result in a significantincrease of the tyrosine phosphorylation of various other cellularproteins in the activated cells. This result is not completelyunexpected in view of the minimal changes in tyrosine phosphorylationof various proteins in anti-IgM-stimulated Lyn-deficient B cellsas compared with wild-type B cells (16). Hence, both in B cellantigen receptor- and RP-105-dependent signaling pathways Lynmight be responsible for the phosphorylation of substrates theexpression and/or degree of phosphorylation of which do not allowtheir detection by anti-phosphotyrosine immunoblot analysis ofcrude cell lysates.

The defective RP-105-mediated activation of Lyn-deficient and xid B cells suggests a possible link between Lyn and Btk inthe RP-105 signaling cascade. Among the Src-family PTKs expressedin B cells, Lyn seems to play a leading role in antigen receptor-mediatedphosphorylation and activation of Btk (31). The lack of effectof Blk and Fyn on RP-105-induced B cell activation suggests thatamong the three major Src-family PTKs in B cells Lyn is likelyto be responsible for Btk activation by RP-105.

As with Lyn-deficient and xid B cells, PKC $beta$ I/II-deficient cells cannot be successfully activated by anti-RP-105. The abilityof Btk to bind PKC $beta$ I/II and the virtual identity of immunodeficiencysyndromes in xid and PKC $beta$ I/II-deficient mice (18) strongly supportthe existence of a Btk/ PKC $beta$ I/II signaling module and its importancefor B cell activation. In B cells, PKC $beta$ I/II together with PKC $alpha$ represent the subfamily of PKCs the activation of which is dependenton Ca²⁺ and diacylglycerol (40). Importantly, PKC $beta$ I/II appears to beactivated by significantly lower concentrations of Ca²⁺ than PKC $alpha$ (41, 42). Therefore, it seems likely that the veryslow and gradual Ca²⁺ mobilization induced by anti-RP-105 would be sufficient to inducethe activation of PKC $beta$ I/II, but not to induce the activation ofPKC $alpha$ . This hypothesis is currently under investigation.

Several lines of evidence support the importance of MAP kinase in RP-105-mediated activation of B cells. First, the activationof B cells by RP-105 leads to activation of MAP kinase isoformsErk2, p38, and Jun kinase (JNK1/2). Second, anti-RP-105 failsto induce proliferation of B cells expressing the dominant negativeform of Erk-specific (43, 44) MAPK kinase (MEK). The impairedRP-105-mediated activation of all three MAP kinase isoforms inthe absence of Lyn and our preliminary data on the lack of MAPkinase activation in xid B cells support a possible connectionbetween the RP-105 and MAP kinase signaling cascades via the Lyn-Btk/PKC $beta$ I/IImodule.

The similarity between toll and RP-105 as well as the ability of anti-RP-105 antibody to induce polyclonal activation of Bcells in vitro supports a possible involvement of RP-105 in theregulation of innate immune responses. The activation of lymphocytesduring innate immune response plays an important role in the efficientrecruitment of activated B cells into antigen-driven adaptiveresponses (3). However, it seems conceivable that the switchfrom innate to adaptive immune responses may require the existenceof mechanisms promoting antigen-specific responses at the expenseof polyclonal B cell activation. In this study we have tried toaddress the mechanism of negative regulation of RP-105-mediatedB cell activation by antigen receptor-derived signal(s). Involvementof Lyn, Btk, PKC $beta$ I/II, and MAP kinases in both sIgM- and RP-105-mediatedactivation implies the existence of a signaling pathway(s) commonfor both of the receptors. In contrast to Btk and PKC $beta$ I/II, whichboth play positive roles in anti-RP-105- and IgM-mediated B cellactivation, Lyn appears to have different functions in sIgM- andRP-105-mediated signaling. Although the sIgM-mediated MAP kinaseactivation is negatively controlled by Lyn (16), the presenceof Lyn is essential for RP-105-induced MAP kinase activation.The relatively stronger activation of Lyn kinase by anti-IgM thanby anti-RP-105 may reflect more efficient recruitment of Lyn tothe B cell antigen receptor (BCR) complex as compared with theputative RP-105 signaling complex. In such a case the simultaneousligation of BCR and RP-105 will reduce the amount of Lyn thatcould be used by RP-105 signaling complex and block the RP-105-inducedMAP kinase activation. This, in turn, may lead to the onset ofthe antigen receptor-specific pattern of MAP kinase activationand reprogramming of B cell responses. Assuming that RP-105 activationin vivo is regulated by specific ligand(s), the antagonistic relationbetween antigen receptor- and RP-105-mediated signaling predictsa temporal and/or spatial separation of putative RP-105 ligand-and antigen- induced B cell activation during immune responses.

	Footnotes

Address correspondence to Alexander Tarakhovsky, Laboratory of Lymphocyte Signaling, Institute for Genetics, University of Köln, Weyertal 121, D-50931 Köln, Germany. Phone: 49-221-470 4319; Fax: 49-221-470 4970; E-mail: sasha{at}mac.genetik.uni-koeln.de

Received for publication 26 March 1998 and in revised form 17 April 1998.

We thank Roger Perlmutter for the fyn^/ mice. We thank Tim Bender, Jonathan Howard, Kaoru Saijo, Christian Schmedt for discussionand critical reading of the manuscript, and Sigrid Irlenbuschfor technical assistance.

This work was supported by the Deutsche Forschungsgemeinschaft through SFB 243 and by the National Institutes of Health (DK50267and HL54476).

Abbreviations used in this paper BCR, B cell antigen receptor; CsA, cyclosporin A; dnMEK, double negative mutant of MEK; Fc $gamma$ R, Fc $gamma$ receptors; MAP, mitogen-activated protein; MEK, MAP kinase kinase; PAMPS, pathogen-associated molecular pattern; PKC $beta$ I/II, protein kinase C $beta$ I/II; PRR, pattern recognition receptor; PTK, protein tyrosine kinase; sIgM, surface IgM.

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The Molecular Mechanism of B Cell Activation by toll-like Receptor Protein RP-105

Copyright © 1998 by The Rockefeller University Press. 0022-1007/98/07/93/09 $2.00

Copyright © 1998 by The Rockefeller University Press.
0022-1007/98/07/93/09 $2.00