The crystal structure of a TIR domain from Arabidopsis thaliana reveals a conserved helical region unique to plants

Plants use a highly evolved immune system to exhibit defense response against microbial infections. The plant TIR domain, together with the nucleotide‐binding (NB) domain and/or a LRR region, forms a type of molecule, named resistance (R) proteins, that interact with microbial effector proteins and elicit hypersensitive responses against infection. Here, we report the first crystal structure of a plant TIR domain from Arabidopsis thaliana (AtTIR) solved at a resolution of 2.0 Å. The structure consists of five β‐strands forming a parallel β‐sheet at the core of the protein. The β‐strands are connected by a series of α‐helices and the overall fold mimics closely that of other mammalian and bacterial TIR domains. However, the region of the αD‐helix reveals significant differences when compared with other TIR structures, especially the αD3‐helix that corresponds to an insertion only present in plant TIR domains. Available mutagenesis data suggest that several conserved and exposed residues in this region are involved in the plant TIR signaling function.     

The STIR-domain superfamily in signal transduction,development and immunity

We have identified a conserved sequence segment in transmembrane receptors (including SEFs, IL17Rs) and soluble factors (including CIKS/ACT1) in eukaryotes and bacteria - the SEFIR domain. This sequence domain is part of the new STIR domain superfamily comprising also the TIR domain known to mediate TIR-TIR homotypic interactions. In TOLL/IL1R-like pathways, the cytoplasmically localized TIR domain of a receptor and the TIR domain of a soluble adaptor interact physically and activate signalling. The similarity between the SEFIR and TIR domains involves the conserved boxes 1 and 2 of the TIR domain that are implicated in homotypic dimerization, but there is no sequence similarity between SEFIR domains and the TIR sequence box 3. By analogy, we suggest that SEFIR-domain proteins function as signalling components of Toll/IL-1R-similar pathways and that their SEFIR domain mediates physical protein-protein interactions between pathway components.     

The Brucella TIR-like protein TcpB interacts with the death domain of MyD88

The pathogen Brucella melitensis secretes a Toll/interleukin-1 receptor (TIR) domain containing protein that abrogates host innate immune responses. In this study, we have characterized the biochemical interactions of Brucella TIR-like protein TcpB with host innate immune adaptor proteins. Using protein-fragment complementation assays based on Gaussia luciferase and green fluorescent protein, we find that TcpB interacts directly with MyD88 and that this interaction is significantly stronger than the interaction of TcpB with TIRAP, the only other adaptor protein that detectably interacts with TcpB. Surprisingly, the TcpB-MyD88 interaction depends on the death domain (DD) of MyD88, and TcpB does not interact with the isolated TIR domain of MyD88. TcpB disrupts MyD88(DD)-MyD88(DD), MyD88(DD)-MyD88(TIR) and MyD88(DD)-MyD88 interactions but not MyD88-MyD88 or MyD88(TIR)-MyD88(TIR) interactions. Structural models consistent with these results suggest how TcpB might inhibit TLR signaling by targeting MyD88 via a DD-TIR domain interface.     

Biophysical analysis of the EPEC translocated intimin receptor-binding domain

Enteropathogenic Escherichia coli (EPEC) are Gram (-) bacteria responsible for widespread illness in the form of diarrhea. EPEC cells attach to the intestinal epithelium using a Type III secretion system common to many Gram (-) bacteria. The translocated intimin receptor (TIR) is the first protein secreted through the EPEC secretion complex, and is absolutely required for pathogenesis. It inserts into the intestinal epithelium, serving as an anchor responsible for the attachment of EPEC to the host epithelial cell. Intimin is a transmembrane protein displayed on the EPEC cell surface with an extracellular domain that binds TIR. Observation of a TIR-TIR dimer in the X-ray co-crystal structure of the extracellular domains of intimin and TIR raised the question of how these protein domains interact and function in solution. Herein we report that the extracellular domain of TIR exists in a folded and active monomeric state in solution, as confirmed by analytical ultracentrifugation, analytical size-exclusion HPLC, isothermal titration calorimetry, and surface plasmon resonance.     

A bioinformatic approach to the identification of bacterial proteins interacting with Toll-interleukin 1 receptor-resistance (TIR) homology domains

Members of the Toll-like receptor (TLR) family are currently under intense scrutiny for their role in the sampling and recognition of pathogens. It has already been reported that both vaccinia virus and Yersinia spp. express proteins that help them evade the TLR mediated immune response, acting through the Toll-interleukin-1 receptor-resistance (TIR) domain and leucine-rich repeat region of the host TLRs respectively. The TIR domain is involved in the dimerisation of the TLRs and their complexation with their adapter molecules. We tested here the hypothesis that bacteria have the ability to secrete proteins containing similar motifs to the intracellular TIR domains that are involved in the TIR-TIR interaction necessary for the subsequent signal transmission. Based upon their sequence homology, proteins expressing TIRs have been divided into three sub-classes, based around the TLRs, the TLR adapter proteins, and the interleukin-1 and -18 adapter proteins. The highly conserved regions from these separate sub-families were then used to identify similar bacterial proteins. The bacterial proteins identified were then included in an iterative MEME-BLAST process to broaden the search. Tollip, a known TLR antagonist and adapter protein, was included in this investigation although it does not fit into any of the three sub-classes outlined above. If suitable bacterial proteins had been identified, it would signify that certain bacteria had evolved a mechanism to aid them in avoiding detection by the innate immune system acting through the TIR domains. At this stage one has to conclude that there is no evidence currently available suggesting such a mechanism, when using the strategy applied here.     

Structural insights into TIR domain specificity of the bridging adaptor Mal in TLR4 signaling

MyD88 adaptor-like protein (Mal) is a crucial adaptor that acts as a bridge to recruit the MyD88 molecule to activated TLR4 receptors in response to invading pathogens. The specific assembly of the Toll/interleukin-1 receptor (TIR) domains of TLR4, Mal and MyD88 is responsible for proper signal transduction in the TLR4 signaling pathway. However, the molecular mechanism for the specificity of these TIR domains remains unclear. Here, we present the crystal structure of the TIR domain of the human Mal molecule (Mal-TIR) at a resolution of 2.4 Å. Unexpectedly, Mal-TIR exhibits an extraordinarily long AB loop, but no αB helix or BB loop, distinguishing it from other TIR domains. More importantly, the Mal-TIR AB loop is capable of mediating direct binding to the TIR domains of TLR4 and MyD88 simultaneously. We also found that Mal-TIR can form a back-to-back dimer that may resemble the dimeric assembly of the entire Mal molecule. Our data demonstrate the bridge role of the Mal-TIR domain and provide important information about TIR domain specificity.     

Molecular evolution of SRP cycle components: functional implications.

Signal recognition particle (SRP) is a cytoplasmic ribonucleoprotein that targets a subset of nascent presecretory proteins to the endoplasmic reticulum membrane. We have considered the SRP cycle from the perspective of molecular evolution, using recently determined sequences of genes or cDNAs encoding homologs of SRP (7SL) RNA, the Srp54 protein (Srp54p), and the alpha subunit of the SRP receptor (SR alpha) from a broad spectrum of organisms, together with the remaining five polypeptides of mammalian SRP. Our analysis provides insight into the significance of structural variation in SRP RNA and identifies novel conserved motifs in protein components of this pathway. The lack of congruence between an established phylogenetic tree and size variation in 7SL homologs implies the occurrence of several independent events that eliminated more than half the sequence content of this RNA during bacterial evolution. The apparently non-essential structures are domain I, a tRNA-like element that is constant in archaea, varies in size among eucaryotes, and is generally missing in bacteria, and domain III, a tightly base-paired hairpin that is present in all eucaryotic and archeal SRP RNAs but is invariably absent in bacteria. Based on both structural and functional considerations, we propose that the conserved core of SRP consists minimally of the 54 kDa signal sequence-binding protein complexed with the loosely base-paired domain IV helix of SRP RNA, and is also likely to contain a homolog of the Srp68 protein. Comparative sequence analysis of the methionine-rich M domains from a diverse array of Srp54p homologs reveals an extended region of amino acid identity that resembles a recently identified RNA recognition motif. Multiple sequence alignment of the G domains of Srp54p and SR alpha homologs indicates that these two polypeptides exhibit significant similarity even outside the four GTPase consensus motifs, including a block of nine contiguous amino acids in a location analogous to the binding site of the guanine nucleotide dissociation stimulator (GDS) for E. coli EF-Tu. The conservation of this sequence, in combination with the results of earlier genetic and biochemical studies of the SRP cycle, leads us to hypothesize that a component of the Srp68/72p heterodimer serves as the GDS for both Srp54p and SR alpha. Using an iterative alignment procedure, we demonstrate similarity between Srp68p and sequence motifs conserved among GDS proteins for small Ras-related GTPases. The conservation of SRP cycle components in organisms from all three major branches of the phylogenetic tree suggests that this pathway for protein export is of ancient evolutionary origin.     

Crystal Structures of the Toll/Interleukin-1 Receptor (TIR) Domains from the Brucella Protein TcpB and Host Adaptor TIRAP Reveal Mechanisms of Molecular Mimicry

The Toll/IL-1 receptor (TIR) domains are crucial innate immune signaling modules. Microbial TIR domain-containing proteins inhibit Toll-like receptor (TLR) signaling through molecular mimicry. The TIR domain-containing protein TcpB from Brucella inhibits TLR signaling through interaction with host adaptor proteins TIRAP/Mal and MyD88. To characterize the microbial mimicry of host proteins, we have determined the X-ray crystal structures of the TIR domains from the Brucella protein TcpB and the host adaptor protein TIRAP. We have further characterized homotypic interactions of TcpB using hydrogen/deuterium exchange mass spectrometry and heterotypic TcpB and TIRAP interaction by co-immunoprecipitation and NF-κB reporter assays. The crystal structure of the TcpB TIR domain reveals the microtubule-binding site encompassing the BB loop as well as a symmetrical dimer mediated by the DD and EE loops. This dimerization interface is validated by peptide mapping through hydrogen/deuterium exchange mass spectrometry. The human TIRAP TIR domain crystal structure reveals a unique N-terminal TIR domain fold containing a disulfide bond formed by Cys⁸⁹ and Cys¹³⁴. A comparison between the TcpB and TIRAP crystal structures reveals substantial conformational differences in the region that encompasses the BB loop. These findings underscore the similarities and differences in the molecular features found in the microbial and host TIR domains, which suggests mechanisms of bacterial mimicry of host signaling adaptor proteins, such as TIRAP.     

斜带石斑鱼TLR3基因的克隆及其在刺激隐核虫感染时的表达分析

TLR3(Toll like receptor 3)是Toll样受体家族的重要成员,通过识别病原相关分子模式,诱导宿主天然免疫应答。研究从斜带石斑鱼(Epinephelus coioides)中克隆得到TLR3 cDNA序列,全长为2937 bp,包括107bp的5′非编码区、100 bp的3′非编码区和编码909个氨基酸的2730 bp的开放阅读框。TLR3全长氨基酸序列包含1个信号肽、18个富含亮氨酸的重复序列(Leucine-rich Repeat LRR)、1个跨膜结构域和1个胞内TIR结构域(IL-R1 homologous region)。同源比对显示,斜带石斑鱼TLR3与其他已报道硬骨鱼类的TLR3具有较高的同源性(52%—67%)。组织表达分析显示,TLR3在健康斜带石斑鱼的组织中具有较广的表达分布,其中在前脑、体肾和脾脏中表达量较高。刺激隐核虫(Cryptocaryon irritans)感染斜带石斑鱼后:在皮肤中TLR3的表达量呈现先降低后升高的趋势,从感染后第7天开始上调,并在第10天达到高峰;而在脾脏中,TLR3的表达量在感染6h时就显著上调并达到峰值。结果表明斜带石斑鱼TLR3在抗刺激隐核虫的免疫应答过程中可能发挥重要作用。     

Integrin evolution: insights from ascidian and teleost fish genomes.

Integrins are a family of alphabeta heterodimeric receptors essential to cell adhesion in all metazoans. In humans, the family consists of 18 alpha and 8 beta subunits that combine to form 24 dimers. Here, we present phylogenetic reconstructions for the alpha and beta integrin subunits based on sequences from 24 invertebrate and vertebrate species, including the fully sequenced genomes of the ascidian Ciona intestinalis (a urochordate) and the pufferfish Takifugu rubripes (a teleost). Both genomes contain integrin alpha subunits that have the inserted alphaI domain. As for the one alphaI domain containing integrin alpha subunit discovered earlier from the ascidian Halocynthia roretzi, the Ciona alphaI domains are missing the distinctive characteristics of mammalian collagen receptors and segregate from all vertebrate alphaI domain integrins in a phylogenetic tree, forming a new subgroup of alpha subunits with alphaI domains. Each of the pufferfish alphaI domain sequences does have characteristics of the collagen receptor alphaI domains, but no leukocyte-specific alphaI domains were found in pufferfish. Comparative protein modeling suggests that several of these fish alphaI domains are structurally compatible with binding to a GFOGER sequence in a collagen triple helix.     

Identification, sequence, and mapping of the mouse multiple PDZ domain protein gene, Mpdz.

The PDZ domain gained its name from the three proteins that were first seen to have homology by virtue of these domains, the mammalian postsynaptic density protein, PSD-95, the Drosophila discs-large septate junction protein, DLG, and the mammalian epithelial tight-junction protein zona occludens, ZO-1. Over 50 PDZ domain-containing genes have been recognized so far from almost any organism subjected to sequencing, including mammals, nematodes, yeast, plants, and bacteria. The domain consists of an approximately 90-amino-acid-residue unit, which is often repeated in the protein. The majority of residues form a conserved spatial structure while a few amino acids in critical positions confer protein binding specificity. A subgroup of PDZ domains have been shown to recognize a short carboxy-terminal amino acid motif, T/SXV (Ser/Thr-X-Val-COO-), where X is any amino acid. We have identified and completely sequenced a gene, Mpdz, that encodes a mouse protein containing 13 such domains. We have also mapped the gene to a series of overlapping deletions on mouse chromosome 4 and can therefore determine that its function is not essential for embryonic development or neonatal survival.     

Identification of interaction sites for dimerization and adapter recruitment in Toll/interleukin-1 receptor (TIR) domain of Toll-like receptor 4

Toll-like receptor signaling requires interactions of the Toll/IL-1 receptor (TIR) domains of the receptor and adapter proteins. Using the mammalian protein-protein interaction trap strategy, homology modeling, and site-directed mutagenesis, we identify the interaction surfaces in the TLR4 TIR domain for the TLR4-TLR4, TLR4-MyD88 adapter-like (MAL), and TLR4-TRIF-related adapter molecule (TRAM) interaction. Two binding sites are equally important for TLR4 dimerization and adapter recruitment. In a model based on the crystal structure of the dimeric TLR10 TIR domain, the first binding site mediates TLR4-TLR4 TIR-TIR interaction. Upon dimerization, two identical second binding sites of the TLR4 TIR domain are juxtaposed and form an extended binding platform for both MAL and TRAM. In our mammalian protein-protein interaction trap assay, MAL and TRAM compete for binding to this platform. Our data suggest that adapter binding can stabilize the TLR4 TIR dimerization.     

A TIR Domain Protein from E. faecalis Attenuates MyD88-Mediated Signaling and NF-κB Activation

Toll-like receptor signaling, mediated by functional Toll/interleukin-1 receptor (TIR) domains, plays a critical role in activating the innate immune response responsible for controlling and clearing infection. Bacterial protein mimics of components of this signaling pathway have been identified and function through inhibition of interactions between Toll-like receptors (TLRs) and their adaptor proteins, mediated by TIR domains. A previously uncharacterized gene, which we have named tcpF (for TIR domain-containing protein in E. faecalis) was identified in the genome of Enterococcus faecalis V583, and predicted to encode a protein resembling mammalian and bacterial TIR proteins. We overexpressed and purified TcpF from E. coli and found that the recombinant protein could bind to phosphatidylinositol phosphates in vitro, suggesting a mechanism by which TcpF may be anchored to the plasma membrane in close proximity to TIR domains of TLRs and adaptor proteins. Purified TcpF was also found to interact specifically with the TIR adaptor protein MyD88, and this interaction was dependent on the BB loop domain in the Box 2 region of TcpF. Despite no evidence of TcpF being a secreted protein, recombinant TcpF was effectively able to enter RAW264.7 cells in vitro although the mechanism by which this occurs remains to be determined. Overexpression of TcpF in mammalian cells suppressed the NF-κB activation induced by bacterial lipoteichoic acid. A mutant lacking the tcpF gene was attenuated for survival in macrophages, with increased ability to activate NF-κB compared to the wild type strain. Complementation in trans restored growth, and inhibition of NF-κB, to that of wild type levels. No appreciable difference in bacterial persistence, dissemination or pathogenesis was observed between the wild type and mutant in a mouse peritonitis model however, which suggested either a subtle role for TcpF or functional overlap with other redundant factor(s) in this virulence model.     

Structural complementarity of Toll/interleukin-1 receptor domains in Toll-like receptors and the adaptors Mal and MyD88

The Toll/interleukin 1 receptor (TIR) domain is a region found in the cytoplasmic tails of members of the Toll-like receptor/interleukin-1 receptor superfamily. The domain is essential for signaling and is also found in the adaptor proteins Mal (MyD88 adaptor-like) and MyD88, which function to couple activation of the receptor to downstream signaling components. Experimental structures of two Toll/interleukin 1 receptor domains reveal a alpha-beta-fold similar to that of the bacterial chemotaxis protein CheY, and other evidence suggests that the adaptors can make heterotypic interactions with both the receptors and themselves. Here we show that the purified TIR domains of Mal and MyD88 can form stable heterodimers and also that Mal homodimers and oligomers are dissociated in the presence of ATP. To identify structural features that may contribute to the formation of signaling complexes, we produced models of the TIR domains from human Toll-like receptor 4 (TLR4), Mal, and MyD88. We found that although the overall fold is conserved the electrostatic surface potentials are quite distinct. Docking studies of the models suggest that Mal and MyD88 bind to different regions in TLRs 2 and 4, a finding consistent with a cooperative role of the two adaptors in signaling. Mal and MyD88 are predicted to interact at a third non-overlapping site, suggesting that the receptor and adaptors may form heterotetrameric complexes. The theoretical model of the interactions is supported by experimental data from glutathione S-transferase pull-downs and co-immunoprecipitations. Neither theoretical nor experimental data suggest a direct role for the conserved proline in the BB-loop in the association of TLR4, Mal, and MyD88. Finally we show a sequence relationship between the Drosophila protein Tube and Mal that may indicate a functional equivalence of these two adaptors in the Drosophila and vertebrate Toll pathways.     

Molecular innovations in plant TIR-based immunity signaling

A protein domain (Toll and Interleukin-1 receptor [TIR]-like) with homology to animal TIRs mediates immune signaling in prokaryotes and eukaryotes. Here, we present an overview of TIR evolution and the molecular versatility of TIR domains in different protein architectures for host protection against microbial attack. Plant TIR-based signaling emerges as being central to the potentiation and effectiveness of host defenses triggered by intracellular and cell-surface immune receptors. Equally relevant for plant fitness are mechanisms that limit potent TIR signaling in healthy tissues but maintain preparedness for infection. We propose that seed plants evolved a specialized protein module to selectively translate TIR enzymatic activities to defense outputs, overlaying a more general function of TIRs.

Plants have evolved specialized protein modules to connect TIR domain signaling to Ca²⁺ influx and mount effective defense responses.     

A communication network within the cytoplasmic domain of toll-like receptors has remained conserved during evolution

Toll/IL-1R (TIR) domain, that is, the cytoplasmic domain, in toll-like receptors (TLRs) from different species showed high sequence conservation in stretches spread across the surface as well as the core of the domain. To probe the structure–function significance of these residues, especially those coming from the core of TIR domains, we analyzed molecular dynamics trajectories of sequence similarity based models of human TIR domains. This study brought forth that N-terminal of the TIR domain simultaneously interacts with the flanking residues of the BB loop and central β-sheets. At the same time, residues of the central β-strands form favorable contacts with the DD loop and C-terminal, thus forming a two-way circuit between the N- and C-termini. In this work, the array of intradomain interactions is termed as communication network. Importantly, the “hubs” of this communication network were found to be conserved in all human TLRs. Earlier mutagenesis–function correlation work brought forth that certain mutations in the “core” of the TIR domain of TLR4 (e.g. in IFI767–769AAA and L815A) led to almost complete abrogation of signaling and reasoning for this dramatic loss-of-function has remained unclear, since these sites are not surface exposed. Using MD studies, we show here that this communication network gets disrupted in mutants of human TLR4 which were earlier reported to be functionally compromised. Extension of MD studies to heterodimer of TLR1/2 suggested that this evolutionarily conserved communication network senses the interactions formed upon dimerization and relays it to surfaces which are not involved in direct interdomain contacts.     

The first membrane spanning region of the lamin B receptor is sufficient for sorting to the inner nuclear membrane

The lamin B receptor (LBR) is a polytopic integral membrane protein localized exclusively in the inner nuclear membrane domain of the nuclear envelope. Its cDNA deduced primary structure consists of a highly charged amino-terminal domain of 205 residues that faces the nucleoplasm followed by a hydrophobic domain with eight potential transmembrane segments. To identify determinants that sort LBR from its site of integration (RER and outer nuclear membrane) to the inner nuclear membrane, we prepared full-length, truncated, and chimeric cDNA constructs of chick LBR, transfected these into mammalian cells and detected the expressed protein by immunofluorescence microscopy using appropriate antibodies. Surprisingly, we found that the determinants for sorting of LBR to the inner nuclear membrane reside in a region comprising its first transmembrane sequence plus flanking residues on either side. The other transmembrane regions as well as the nucleoplasmic domain are not required for sorting. We propose that the first transmembrane segment of LBR interacts specifically with another transmembrane segment and consider several mechanisms by which such specific interaction could result in sorting to the inner nuclear membrane.