Cloning and Characterization of Two Toll/Interleukin-1 Receptor-Like Genes TIL3 and TIL4: Evidence for a Multi-Gene Receptor Family in Humans

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Blood, Vol. 91 No. 11 (June 1), 1998: pp. 4020-4027
Cloning and Characterization of Two Toll/Interleukin-1 Receptor-Like Genes TIL3 and TIL4: Evidence for a Multi-Gene Receptor Family in Humans

By Preet M. Chaudhary, Camari Ferguson, Vilaska Nguyen, Oanh Nguyen, Hillary F. Massa, Michael Eby, Alan Jasmin, Barbara J. Trask, Leroy Hood, and Peter S. Nelson
From the Department of Medicine and Molecular Biotechnology, University of Washington, Seattle, WA.

  ABSTRACT

Abstract
Introduction
Methods
Results
Discussion
References

Remarkable structural and functional similarities exist between the Drosophila Toll/Cactus/Dorsal signaling pathway and themammalian cytokine-mediated interleukin-1 receptor (IL-1R)/I- $kappa$ B/NF- $kappa$ Bactivation cascade. In addition to a role regulating dorsal-ventralpolarity in the developing Drosophila embryo, signaling throughDrosophila Toll (dToll) activates the nonclonal, or innate, immuneresponse in the adult fly. Recent evidence indicates that a humanhomologue of the dToll protein participates in the regulationof both innate and adaptive human immunity through the activationof NF- $kappa$ B and the expression of the NF- $kappa$ B-controlled genes IL-1,IL-6, and IL-8, thus affirming the evolutionary conservation ofthis host defense pathway. We report here the cloning of two novelhuman genes, TIL3 and TIL4 (Toll/IL-1R-like-3, -4) that exhibithomology to both the leucine-rich repeat extracellular domainsand the IL-1R-like intracellular domains of human and DrosophilaToll. Northern analysis showed distinctly different tissue distributionpatterns with TIL3 expressed predominantly in ovary, peripheralblood leukocytes, and prostate, and TIL4 expressed primarily inperipheral blood leukocytes and spleen. Chromosomal mapping byfluorescence in situ hybridization localized the TIL3 gene tochromosome 1q41-42 and TIL4 to chromosome 4q31.3-32. Functionalstudies showed that both TIL3 and TIL4 are able to activate NF- $kappa$ B,though in a cell type-dependent fashion. Together with human Toll,TIL3 and TIL4 encode a family of genes with conserved structuraland functional features involved in immune modulation.

  INTRODUCTION

Abstract
Introduction
Methods
Results
Discussion
References

THE DROSOPHILA TOLL gene (dToll) encodes a transmembrane protein with features of a signal-transducing receptor.¹^,² Theintracellular and extracellular domains of dToll exhibit strikingstructural and functional similarities with proteins of two distinctfamilies: the interleukin-1 receptor (IL-1R)-like family³^,⁴and the superfamily of leucine-rich repeat (LRR) proteins.⁵dToll is involved in establishing the dorsal/ventral axis of thedeveloping Drosophila embryo through a conserved signaling pathwayinvolving the downstream effectors dorsal, an Rel family memberwith homology to the transcription factor NF- $kappa$ B,⁶ and cactus,a protein with structural homology to I- $kappa$ B.⁷

The dToll signaling pathway is also involved in the innate nonspecific Drosophila immune response through the induction ofgenes encoding antibacterial⁸ and antifungal⁹ peptides.The immune response modulated by dToll reflects an ancestral conservedsystem that has homologous components in plants¹⁰ and vertebrates,as exemplified by the IL-1/NF- $kappa$ B-mediated induction of the mammalianinflammatory response.¹¹ Mutagenesis and deletion analyses haveshown that amino acid residues conserved between the IL-1R anddToll cytoplasmic domains are essential for signal transductionby these receptors.¹²^,¹³ Experiments involving the deletionof the extracellular LRR regions of dToll showed a dominant gain-of-functionactivity, suggesting that dToll functions as a receptor whoseintrinsic intracellular signaling activity is regulated by itsextracellular domain.¹³^,¹⁴

Two human genes with homology to the Drosophila Toll sequence have recently been described. Human Toll (hToll) is a type Itransmembrane protein with an extracellular domain consistingof LRRs and a cytoplasmic domain homologous to the cytoplasmicdomain of the human IL-1R protein.¹⁵ A constitutively activehToll mutant induced the activation of NF- $kappa$ B and the expressionof NF- $kappa$ B-controlled genes for inflammatory cytokines. These resultssupport the conservation of a host-defense pathway between Drosophilaand humans.¹⁵ A second gene, TIL (Toll/IL-1R-like), also encodesa protein with regions homologous to the intracellular and extracellulardomains of dToll.¹⁶ However, TIL was unable to activate NF- $kappa$ Bthrough a chimeric IL-1R/TIL receptor complex.¹⁷

Three additional Drosophila genes, 18-wheeler, tlr (Toll-like receptor) and MstProx, exhibit homology to dToll involving boththe intracellular IL-1R-like domain and the extracellular LRRs.Eighteen-wheeler is required for Drosophila morphogenesis andis thought to function as a cell adhesion or receptor moleculethat facilitates cell movements.¹⁸ Drosophila tlr is also involvedin embryogenesis with a potential role in cell-to-cell interactionsat critical boundaries during development.¹⁹ MstProx is a recentlycloned Drosophila gene that has not been extensively characterized.¹⁷

Based on the pivotal role of Drosophila Toll in both development and immune regulation, we undertook a database search toidentify other human genes with sequence homology to dToll. Wereasoned that evidence of a family of Toll-like genes in Drosophilacould indicate a similar family of genes in humans. Two novelsequences were identified that we have named TIL3 and TIL4 (Toll/IL-1R-like-3and -4). In this study we report the isolation and characterizationof the full-length cDNAs for TIL3 and TIL4, including their chromosomalassignments and tissue expression patterns. We also show thatTIL3 and TIL4 activate NF- $kappa$ B in a cell type-dependent fashion.Together with hToll, TIL3 and TIL4 encode a family of genes withstructural and functional similarities that may serve to modulatethe human immune response.

  MATERIALS AND METHODS

Abstract
Introduction
Methods
Results
Discussion
References

Cell culture and general methods. DNA manipulations including transformation, plasmid preparation, and gel electrophoresis were performed according to standardprocedures.²⁰ Restriction and modification enzymes (BoehringerMannheim, Inc, Life Technologies, Rockville, MD) were used inaccordance with the manufacturers' recommendations. MCF-7 breastcarcinoma cells and 293T cells were cultured in Dulbecco's modifiedEagle's medium (DMEM; Life Technologies) supplemented with 10%fetal calf serum. BHK (baby hamster kidney) cells were grown inDMEM supplemented with 5% fetal calf serum.

DNA sequencing and analysis. Sequencing was performed by the dideoxy chain-termination method using Taq dye primer and dye terminator kits (Applied Biosystems,Foster City, CA). The nucleotide sequences were analyzed withan ABI 377 automated sequencer (Applied Biosystems). The finalsequences were confirmed by sequencing both strands. Sequencehomology searches and comparisons were performed using BLASTNand BLASTX algorithms on the National Center for BiotechnologyInformation (NCBI) web-server. Sequence assembly was performedusing the Phred, Phrap, and Consed programs (http://chimera.biotech.washington.edu/UWGC/).

Cloning of TIL3 and TIL4. Several human sequences in the NCBI expressed-sequence-tag (EST) database were identified with statistically significant homologyto the Drosophila Toll gene. One EST (IMAGE Consortium Clone 684668)corresponded to the published human gene KIAA0012/TIL (GenbankID D13637). One EST (IMAGE Consortium Clone ID 202057) correspondedto a published human gene, hToll (Genbank accession U93091).Two others (IMAGE Consortium Clone Ids 80633 and 277229) showinghomology to dToll were obtained (Genome Systems, St Louis, MO)and sequenced in their entirety. Each comprised a partial openreading frame with homology to dToll and hToll. Rapid amplificationof cDNA ends (RACE) was used to obtain full-length cDNAs usinghuman peripheral blood leukocyte and prostate cDNA as template(Clontech, Palo Alto, CA) with gene specific primers TX360L 5 $'$ -CTCTGATGGATTGATGTTTCATC-3 $'$ for TIL3 and TW236L 5 $'$ GAGAGTCACACAGGTAATTTGCTGG 3 $'$ for TIL4. RACEproducts were cloned using the T/A cloning method according tothe manufacturer's instructions (Invitrogen, La Jolla, CA), sequenced,and assembled as described above.

Northern blot analysis. TIL3 (nt 1211-1620) and TIL4 (nt 667-3288) cDNA probes were labeled with ³²P-dCTP (DuPont NEN, Boston, MA) using a random priming labelingkit following the manufacturers instructions (Life Technologies).Adult poly(A)⁺ multiple-tissue Northern blots (Clontech) were hybridized inQuick-hyb solution (Clontech) at 68°C according to the manufacturer'sinstructions. The filters were washed in three changes of 2× SSCwith 0.05% sodium dodecyl sulfate (SDS) at room temperature for30 minutes each followed by two changes of 0.1× SSC with 0.1%SDS at 50°C for 20 minutes each. Equal mRNA loading was assessedby stripping the filter and reprobing with a human ³²P-labeled $beta$ -actin probe. Hybridization and washing conditionswere as described above.

Chromosomal localization by fluorescence in situ hybridization (FISH). TIL3 and TIL4 cDNA probes were labeled as described above and were hybridized to filters of an arrayed human BAC genomic library(Research Genetics, Huntsville, AL). Positive clones were identifiedand subsequently verified by polymerase chain reaction using TIL3and TIL4 gene-specific amplification primers. BAC and plasmidDNA clones were biotinylated by nick translation, prehybridizedin the presence of human Cot1 DNA, and hybridized (at 10 and 50ng/uL, respectively) to metaphase spreads of a normal male followingprocedures described in detail elsewhere.²¹ After hybridizationand washing, the hybridization sites were labeled with fluorescein-conjugatedavidin. The chromosomes, which had previously been released froman early-S methotrexate block in the presence of BrdU, were counterstainedwith DAPI to produce a QFH-like banding pattern. Digital imageprocessing was performed as described elsewhere.²² The locationsof hybridization signals were analyzed in 10 well-spread, well-bandedmetaphases for each sample.

Chimeric constructions. Expression vectors encoding the Fas-hToll, Fas-TIL3, and Fas-TIL4 fusion proteins were made by joining the nucleotides encodingthe extracellular domain of human Fas receptor (aa 1 to 169) tothe nucleotides encoding the transmembrane and cytoplasmic tailof hToll (aa 629 to 841), TIL3 (aa 630 to 858), and TIL4 (aa 584to 784), respectively. The chimeric constructs were cloned intothe pCDNA3 expression vector (Invitrogen).

NF- $kappa$ B assay. For the NF- $kappa$ B reporter assay, 8 × 10⁴ MCF7 human breast cancer cells were transfected in triplicate with 500 ng of the testconstructs or empty vector along with 250 ng of a NF- $kappa$ B reporterconstruct²³ and a LacZ reporter construct (Invitrogen) in a24-well plate using Superfect (Qiagen, Valencia, CA) followingthe manufacturer's instructions. Forty-eight hours after transfection,cells were lysed and luciferase activity was measured using theluciferase assay reagent (Promega, Madison, WI) as described previously.²³Baby hamster kidney fibroblast cells (BHK) and transformed humanepithelial kidney 293T cells were plated as described above andtransfected using the calcium phosphate precipitation method²⁰with luciferase analysis performed after 48 or 24 hours, respectively.

  RESULTS

Abstract
Introduction
Methods
Results
Discussion
References

TIL3 and TIL4 are homologs of the Drosophila Toll gene with homology to IL-1R cytoplasmic domain (IL-1Rcd) and LRR extracellular domain. Two human cDNA sequences in the NCBI database of expressed sequence tags were identified that exhibited significant sequencehomology to the Drosophila Toll protein. These clones were foundto contain partial open reading frames (ORFs) corresponding toTIL3 and TIL4. The RACE methodology was used to obtain full-lengthcDNA clones of these genes.

The nucleotide sequence of the TIL3 cDNA contains an open reading frame of 2,574 bp that starts at the first methionine codonpreceded by an appropriate Kozak consensus sequence for the initiationof translation.²⁴ The predicted protein sequence derived fromthe open reading frame produces an 858-amino acid polypeptide(Fig 1A). The nucleotide sequence of the TIL4 cDNA contains anopen reading frame of 2,352 bp that starts at the first methioninecodon preceded by an appropriate Kozak consensus sequence forthe initiation of translation. The predicted protein sequencederived from the open reading frame produces a 784-amino acidpolypeptide (Fig 1B).

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Fig 1. (A) Amino acid sequence of TIL3. The predicted signal peptide (residues 1 to 30) is underlined. The predicted transmembranesegment (residues 642 to 660) is in bold and underlined. (B) Aminoacid sequence of TIL4. The predicted signal peptide (residues1 to 20) is underlined. The predicted transmembrane segment (residues590 to 609) is in bold and underlined.

The TIL3 and TIL4 amino acid sequences exhibit features of type I integral membrane proteins. Each contains two regions ofhydrophobicity corresponding to a signal peptide located at theamino terminus, and a transmembrane region near the midportion(Fig 1). TIL3 and TIL4 share 40% overall amino acid similarityand 24% amino acid identity (Fig 2). They exhibit homology withboth the intracellular and extracellular regions of the DrosophilaToll,¹ human Toll,¹⁵ and TIL²⁵ proteins (Fig 2).

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Fig 2. (A) Alignment of the amino acid sequence of the cytoplasmic domains of the IL-1R and the Toll/IL-1R-like family members: Drosophilawheeler and Toll, human Toll, TIL, TIL3, and TIL4. Alignmentswere performed using the Clustal algorithm⁴⁹ and Boxshade (http://ulrec3.unil.ch/software/BOX_faq.html).Sequence identity (black) or similarity (gray) between at least40% of the sequence members are shaded. Inactivating dToll mutationsare marked with an asterisk (*).¹³ Critical amino acid residuesfor IL-1R activation of IL-2 are denoted by a solid circle ( $bullet$ ),¹²^,⁴²for IL-1R activation of IL-8 by a cross (+),⁴⁵ and IL-1R activationof NF- $kappa$ B by a box ( $square$ ).⁴³ (B) Alignment of the extracellularLRR terminal-flanking sequences of the LRR proteins TIL3, TIL4,TIL, hToll, dToll, human platelet glycoprotein 1b- $alpha$ (Gp1b- $alpha$ ) and1b- $beta$ (gp1b- $beta$ ),²⁷^,⁴⁷ platelet glycoprotein IX (gpIX),²⁸ leucine-richglycoprotein (LRG),²⁹ and the oncofetal antigen 5T4 (ofg-5T4).³⁰The extracellular region of dToll contains two cysteine-rich LRRdomains (dToll #1 and dToll#2). Sequence identity (black) or similarity(gray) between at least 40% of the sequence members are shaded.The mutations responsible for the dominant, constitutively activedToll proteins are denoted by asterisk (*) and are located inthe second dToll terminal repeat.¹³

The TIL3 and TIL4 polypeptides contain the two distinct structural/functional motifs characteristic of dToll: the IL-1R-likeregion in the cytoplasmic portion of the protein and the LRR domainin the extracellular portion. An amino acid multiple sequencealignment of the cytoplasmic IL-1R-like regions of TIL3, TIL4,and other IL-1R family members is shown in Fig 2A. Several ofthe specific amino acid residues shown to be of functional importancein IL-1R-mediated activities such as activation of IL-2, IL-8,and NF- $kappa$ B are conserved in the predicted TIL3 and TIL4 proteinsequences (Fig 2A). However, several of these critical amino acidsdiverge significantly between the IL-1R and the IL-1R-relatedproteins. For example, two of six residues involved in IL-1R-mediatedNF- $kappa$ B activation, amino acids 518 and 519, are divergent in thehToll sequence. Nonetheless, hToll has been shown to activateNF- $kappa$ B.¹⁵ Further, of three inactivating mutations found in thecytoplasmic portion of the Drosophila Toll protein,¹³ all threewild-type functional residues are conserved in the TIL3 and TILsequences, but only two retain conservation in TIL4, hToll, andIL-1R (Fig 2A).

The similarities among the deduced amino acid sequences of the LRR-flanking regions of the extracellular TIL3 and TIL4 proteinsand other LRR family members are shown in Fig 2B. Previous reportshave emphasized the similarity between the dToll protein and thehuman membrane receptor platelet glycoprotein 1b- $alpha$ (Gp1b- $alpha$ ) byvirtue of their common LRRs¹ and a sequence of 60 amino acidscontaining two to four conserved cysteine residues located immediatelyC-terminal to the block of LRRs.¹³^,²⁶ This sequence is conservedin several other human proteins, including platelet glycoprotein1b- $beta$ ,²⁷ platelet glycoprotein IX,²⁸ serum leucine-rich glycoprotein(LRG),²⁹ and the oncofetal antigen 5T4 (ofg-5T4).³⁰ The highlevel of sequence conservation indicates that this region is likelyto be of structural and/or functional significance. A role forthe conserved cysteine residues in the formation of disulfide-linkedextracellular domains that may be involved in cell adhesion andligand binding has been suggested.²⁶^,³¹

Expression distribution of TIL3 and TIL4. To examine the expression pattern of TIL3 and TIL4, cDNA fragments for each gene were used to probe Northern blots containingpoly(A)⁺ RNA from several human tissues. The TIL3 cDNA hybridized to anmRNA species of approximately 3.3 kb, which was present predominantlyin peripheral blood leukocytes (PBL), ovary, and prostate, andshowed lower expression in other tissues (Fig 3A). Several lessprominent bands of higher molecular weight were also detected.The TIL4 cDNA hybridized to an mRNA species of approximately 2.8kb present predominantly in PBL and spleen with weak expressionin the remaining tissues (Fig 3B). The predominant message sizescorrespond to the full-length TIL3 and TIL4 cDNA clones we haveisolated by RACE.

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Fig 3. Multiple tissue Northern analysis of poly (A)⁺ RNA with TIL3 and TIL4. (A) TIL3 is predominantly expressed in PBL and ovarywith a lower expression in prostate and testis. (B) TIL4 is predominantlyexpressed in PBL. Tissues examined: SP, spleen; TH, thymus; PR,prostate; TE, testis; OV, ovary; SI, small intestine; CO, colon;PBL, peripheral blood leukocytes. A human $beta$ -actin probe was usedas a control for equivalent RNA loading.

Chromosomal localization of TIL3 and TIL4. TIL3 and TIL4 were mapped to their chromosome location by FISH. BACs 22D07 and 21K16, containing TIL3 and TIL4, respectively,were biotinylated and hybridized to metaphase spreads of a normalmale donor. The TIL3 BAC hybridized to three locations, 1q41-q42,9p12, and 9q12-13 (not shown), suggesting that the BAC eitheris chimeric or contains sequences that are present at multiplelocations. To determine which of these locations harbors the TIL3gene, a plasmid, TX667U3288L, containing 2.6 kb of the TIL3 sequencewas used for FISH (Fig 4A). Signals were observed with the plasmidonly at 1q41-q42, thereby localizing the TIL3 gene to this location.FISH analyses of BAC 21K16 place the TIL4 gene at 4q31.3-32 (Fig4B).

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Fig 4. Localization of TIL3 and TIL4 to human chromosome regions 1q41-q42 and 4q31.3-q32, respectively, by FISH. (A) TIL3. Summaryof the locations of hybridization signals observed among 10 mitoticcells hybridized with plasmid TX667U3288L. Signals were observedin the 1q41-q42 region on both homologs (black circles) of 6 cellsand only a single homolog (gray circles) in 4 cells, for an overallefficiency of 80%. Signals were not observed consistently at anyother location. (B) TIL4. Summary of the locations of FISH signalsobserved among 10 mitotic cells hybridized with BAC 21K16, whichcontains TIL4. Hybridization signals were observed at 4q31.3-q32on both homologs in each cell.

TIL3 and TIL4 activate NF- $kappa$ B in a cell type-specific manner. The sequence similarity of the cytoplasmic domains of TIL3 and TIL4 with the type IL-1R suggests that the TIL proteins aresignal transducing molecules that may participate in similar intracellularsignaling pathways. Stimulation of the IL-1R is known to resultin activation of the transcription factor NF- $kappa$ B, and this activityhas been localized to a critical region spanning amino acids 508to 529 of the IL-1R cytoplasmic domain exhibiting considerablehomology to both dToll and hToll.³² As hToll was recently shownto activate NF- $kappa$ B and upregulate inflammatory cytokines,¹⁵ weinvestigated whether the sequence conservation observed betweenTIL3, TIL4, and the IL-1R also reflects a functional conservationwith regard to downstream signaling events. Because the naturalligands for hToll, TIL3, and TIL4 have not been identified, weconstructed chimeric receptors comprising the transmembrane andintracellular regions of TIL3, TIL4, and hToll, each joined tothe extracellular domain of the Fas (CD95) receptor. Fas, a memberof the tumor necrosis factor (TNF) family of receptors, has beenshown to spontaneously aggregate and activate in a ligand-independentfashion when overexpressed in mammalian cells.³³

The chimeric receptors were tested for their ability to activate NF- $kappa$ B in vivo in an overexpression assay. The constructswere transiently transfected into MCF7 human breast carcinomacells, along with a NF- $kappa$ B/luciferase reporter plasmid. Forty-eighthours later, cells were lysed and assayed for luciferase activity.As shown in Fig 5A, all three human Toll-like proteins were ableto activate NF- $kappa$ B when overexpressed in MCF7 cells. The strongestactivation was seen with the Fas-hToll construct. TIL3 and TIL4were also able to activate NF- $kappa$ B in BHK cells (hToll was not assayed)(Fig 5B). A tissue-specific difference in the signaling pathwaysused by the TIL proteins is indicated by the NF- $kappa$ B activationin 293T cells. hToll activated NF- $kappa$ B effectively in these cells,but TIL4 failed to activate NF- $kappa$ B, and TIL3 showed only a weakresponse (Fig 5C). We also compared the ability of TIL3 and TIL4to activate NF- $kappa$ B relative to DR3/WSL/TRAMP/APO3 (hereafter DR3),an NF- $kappa$ B-inducing member of the tumor necrosis factor receptorfamily.³⁴ Although all three receptors could activate NF- $kappa$ Bin MCF7 cells, NF- $kappa$ B activation by DR3 was an order of magnitudegreater than that seen with TIL3 and TIL4 (Fig 5D).

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Fig 5. NF- $kappa$ B activation by hToll, TIL3, and TIL4. Expression plasmids encoding Fas-hToll, Fas-TIL3, Fas-TIL4, or empty vector werecotransfected with a $beta$ -galactosidase (LacZ) expression plasmidinto different cell lines in triplicate. Forty-eight hours latercells were lysed from two of the wells and luciferase activitymeasured as described previously.²³ Cells from the third wellwere fixed with glutaraldehyde (0.5% in phosphate-buffered saline)and stained with X-gal (5-bromo-4-chloro-3-indoxyl-b-D-galactosidase)to obtain relative transfection efficiency.

  DISCUSSION

Abstract
Introduction
Methods
Results
Discussion
References

We have isolated two human cDNAs, TIL3 and TIL4, that exhibit extensive sequence homology with the Drosophila Toll proteinin both the IL-1Rcd and the LRR extracellular domain. TIL3 andTIL4 are also very similar to the previously described human Toll-likegenes, hToll and TIL.¹⁵^,¹⁶ After submission of this manuscript,the cloning and expression profiles of four complete and one partialhuman Toll-like receptors (TLRs) were described.³⁵ These geneswere designated TLRs 1 through 5. The sequence of TIL3 is similarto the partial clone termed TLR5, whereas TIL4 and hToll correspondto TLR2 and TLR4, respectively. In addition to dToll, three additionalDrosophila proteins, designated 18-wheeler, tlr, and MstProx,exhibit both IL1-Rcd and LRR homology. Together, these Toll/IL-1R-likegenes encode a novel family of signal transducing transmembraneproteins with putative functions involving the immune response,morphogenesis, and cell adhesion. The structure of the Toll familyof proteins is biologically unique in combining both the IL-1Rand LRR domains in a single molecule. This configuration has significantfunctional implications in view of the many proteins from diversebiological systems that exhibit homology to these motifs.

The sequence similarity observed between dToll and the IL-1Rcd is highly significant in view of the striking evolutionaryconservation of their respective signal transduction pathwaysinvolving the Drosophila genes dorsal, cactus, pelle, and theirhuman counterparts NF- $kappa$ B, I- $kappa$ B, IRAK, and IRAK2.³⁴^,³⁶ In additionto a functional role in establishing dorsal-ventral polarity inthe developing Drosophila embryo, the dToll signaling pathwayparticipates in the adult Drosophila innate immune response viainduction of antifungal and antibacterial peptides.⁹ The recentdemonstration of the ability of hToll to activate NF- $kappa$ B and induceeffector cytokines such as IL-1, IL-6, and IL-8 provided the firstdirect evidence for the conservation of this pathway of innateimmunity in vertebrates.¹⁵ We have shown here that TIL3 andTIL4 resemble hToll in their ability to activate NF- $kappa$ B, therebyproviding further evidence of the conservation of Toll signalingin mammals. This result is consistent with the high degree ofsequence homology in the cytoplasmic domains of these three proteinsand the cytoplasmic domains of other IL-1R-like proteins, whichare known activators of NF- $kappa$ B in mammals.

The cytoplasmic domains of TIL3, TIL4, and hToll are also homologous to the cytoplasmic domain of the human gene TIL (Fig2A). Previous studies with TIL in the form of a chimeric IL-1Rextracellular domain and TIL intracellular domain failed to activateNF- $kappa$ B in COS7 cells.¹⁷ There are several explanations for thisresult. The NF- $kappa$ B/luciferase reporter assay used in the presentstudy is much more sensitive than the gel-shift assay used inthe TIL study, and a weak activation of NF- $kappa$ B might not have beendetected. Alternatively, although TIL may not activate NF- $kappa$ B inCOS7 cells, it may show activity in other cell types. This possibilityis exemplified by the ability of TIL4 to activate NF- $kappa$ B in MCF7and BHK cells, but not 293T cells.

We also observed a difference in the relative level of activation affected by TIL3 and TIL4 in the different cell lines tested.These cell-dependent behaviors may reflect a difference in theaccessory/adapter molecules that interact with these proteinsand play critical roles in their signal transduction pathways.The distinct tissue expression patterns exhibited by these receptorslend support to cell type-specific activity. Studies with hTollhave shown expression in a wide spectrum of human tissues withthe highest level in spleen and peripheral blood leukocytes includingmonocytes, macrophages, dendritic cells, B cells, and T cells.¹⁵TIL3 is expressed in PBLs, ovary, and prostate, and TIL4 is predominantlyexpressed in PBLs and spleen. The observed amino acid sequencedivergences between these proteins may also influence receptorfunction by providing alternative protein conformations leadingto distinct binding affinities for interacting proteins.

If the signaling pathway involving these Toll/IL-1R-like proteins mirrors the IL-1R pathway, then upstream and downstreamevents will likely involve molecules homologous to those in theIL-1R pathway. The IL-1R is a multisubunit complex,³⁷ as shownby the identification of the IL-1R accessory protein.³⁸ Thedownstream signaling events involve two IL-1R-associated kinases,IRAK³⁹ and IRAK2,⁴⁰ and the recently described putative IL-1Radapter/regulator, MyD88.⁴⁰ Interestingly, the dToll and IL-1signal pathways retain their striking conservation with the findingthat IRAK and IRAK2 are homologous to Pelle, a protein kinasein the dToll pathway.³⁹

The IL-1 and TNF receptor families represent the two known families of cell-surface receptor proteins that can lead to activationof the NF- $kappa$ B pathway in mammalian cells.⁴¹ Our study suggeststhat although both families can activate NF- $kappa$ B, they differ intheir relative activity. The TNF receptor family member DR3 exhibitsmuch stronger stronger NF- $kappa$ B activation than do TIL3 or TIL4.This result may be supported by recent reports suggesting thepresence of distinct downstream adapter proteins, such as TRAF2and TRAF6, that participate in the signal transduction of thesetwo receptor families.⁴¹ However, this conclusion is based onligand-independent receptor activation in a transient transfection-over-expressionsystem. It is possible that the observed difference reflects avariation in the abilities of these two receptor types to self-activatewhen overexpressed, and not in their inherent abilities to activateNF- $kappa$ B in the presence of their cognate ligands. The identificationof ligands for TIL3, TIL4, and hToll will help to define signalspecificity and regulation through the native receptor complex.

The essential functional regions of the dToll and IL-1R proteins have been delineated through detailed deletion and mutationalanalysis experiments. Seven conserved residues of the IL-1Rcdare critical for full signal transduction as assayed by IL-2 activation,¹²^,⁴²and six of seven of these residues are also conserved in the dTollprotein. The human Toll/IL-1-like genes retain 3 or 4 of theseresidues, but only hToll Phe-807 is conserved in all of the Toll/IL-1R-likeproteins and IL-1R (Fig 2A). Several of these conserved residueshave also been shown to be essential for IL-1R activation of NF- $kappa$ B.⁴³The region corresponding to aa 435 to 484 of IL-1R is similarin sequence to the box 1- and box2-like elements present in gp130,the signal-transducing subunit of the IL-6R family.⁴⁴ Aminoacid mutagenesis of the hydrophobic elements within the gp130homologous region in the IL-1R identified several residues criticalfor the capacity to induce IL-8 gene expression.⁴⁵ These residuesare highly conserved in the Toll/IL-1R-like protein family (Fig2A).

Deletion of the extracellular LRR portion of dToll leads to a constitutively active protein.¹⁴ Examination of Drosophilaembryo mutants revealed nine gain-of-function mutations, all locatedin the extracellular domain. Of these mutations, three involvecysteine-to-tyrosine residue changes in the region located immediatelyoutside the transmembrane domain.¹³ These cysteines, adjacentto the LRRs, are thought to be involved in the formation of intramoleculardisulfide bonds,¹³ and are conserved in all of the Toll/IL-1R-likeproteins that we have examined.

LRRs are short protein modules of 20 to 29 amino acids characterized by a periodic arrangement of hydrophobic residues thatare found in a diverse group of extracellular, membrane, and cytoplasmicproteins.⁴⁶ A subset of the LRR protein superfamily comprisesproteins with LRR flanking cysteine clusters, an arrangement thatappears to be a property of adhesive proteins and receptors. Thisgroup includes the TIL/IL-1R-like proteins, leucine-rich glycoprotein,²⁹the metastasis-associated oncofetal antigen 5T4,³⁰ and componentsof the platelet glycoprotein 1b-V-IX complex.²⁷^,²⁸ Plateletglycoprotein 1b is a membrane receptor involved in the adhesionof platelets to subendothelial connective tissue at sites of endothelialdamage.⁴⁷ dToll has also been shown to promote cell adhesionin either a direct manner involving the LRR domains, or indirectlyby transducing an extracellular signal that causes activationof other adhesion molecules on the cell surface.²⁶

In view of their sequence homology with the LRR extracellular domains of dToll and the platelet glycoproteins, it is likelythat the human Toll/IL-1R proteins may also have adhesive properties.It is interesting to speculate how the adhesive and immunoregulatoryfunctions of Toll/IL-1R proteins could be linked. In view of dToll'sdiverse functions in development, immune regulation, and adhesion,the Toll/IL-1 signaling pathway may not be dedicated to specifictarget genes, but instead may control completely divergent genesinvolved in distinct processes.⁴⁸ The intimate involvement ofToll in developmental events coupled with the striking conservationof the Toll signaling pathway from plants to vertebrates shouldmake the Toll/IL-1R-related genes hToll, TIL, TIL3, and TIL4 primecandidates for the investigation of developmentally associateddiseases linked to their respective chromosomal locations.

  FOOTNOTES

   Submitted January 13, 1998; accepted March 9, 1998.
   Supported by the CaPCURE Foundation and the Stowers Institute for Medical Research, a postdoctoral fellowship from the DamonRunyon-Walter Winchell Foundation (P.M.C.), and a grant (DE-GF03-96ER62173)from the United States Department of Energy (O.N., H.F.M., B.J.T.).
   The Genbank accession numbers of TIL3 and TIL4 are AF051151 and AF051152, respectively.
   Address reprint requests to Peter S. Nelson, MD, Department of Molecular Biotechnology, Box 357730 HSB K-360, University ofWashington, Seattle, Washington 98195.
   The publication costs of this article were defrayed in part by page charge payment. This article must therefore be herebymarked "advertisement" is accordance with 18 U.S.C. section 1734solely to indicate this fact.

  ACKNOWLEDGMENT

We thank Steve Lasky and Carol Loretz for sequencing assistance.

  REFERENCES

Abstract
Introduction
Methods
Results
Discussion
References

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