- Open Access
Comparative genomic analysis of the Tribolium immune system
Genome Biology volume 8, Article number: R177 (2007)
Tribolium castaneum is a species of Coleoptera, the largest and most diverse order of all eukaryotes. Components of the innate immune system are hardly known in this insect, which is in a key phylogenetic position to inform us about genetic innovations accompanying the evolution of holometabolous insects. We have annotated immunity-related genes and compared them with homologous molecules from other species.
Around 300 candidate defense proteins are identified based on sequence similarity to homologs known to participate in immune responses. In most cases, paralog counts are lower than those of Drosophila melanogaster or Anopheles gambiae but are substantially higher than those of Apis mellifera. The genome contains probable orthologs for nearly all members of the Toll, IMD, and JAK/STAT pathways. While total numbers of the clip-domain serine proteinases are approximately equal in the fly (29), mosquito (32) and beetle (30), lineage-specific expansion of the family is discovered in all three species. Sixteen of the thirty-one serpin genes form a large cluster in a 50 kb region that resulted from extensive gene duplications. Among the nine Toll-like proteins, four are orthologous to Drosophila Toll. The presence of scavenger receptors and other related proteins indicates a role of cellular responses in the entire system. The structures of some antimicrobial peptides drastically differ from those in other orders of insects.
A framework of information on Tribolium immunity is established, which may serve as a stepping stone for future genetic analyses of defense responses in a nondrosophiline genetic model insect.
Tribolium beetles harbor a range of natural pathogens and parasites, from bacteria to fungi, microsporidians and tapeworms [1, 2]. There is good evidence for genetic variation in resistance to the tapeworm and a linked cost of resistance in terms of growth and reproduction . Cross-generational transfer of immune traits  may occur in Tenebrio molitor, a close relative of Tribolium castaneum. RNA interference experiments demonstrate that Tribolium laccase-2 is responsible for cuticle pigmentation and sclerotization . While these observations are interesting, our knowledge of the genetic constituents of Tribolium immunity is almost blank at the cellular and molecular levels, in contrast to the vast amount of information regarding Drosophila melanogaster and Anopheles gambiae defense responses [6, 7]. Given the high efficiency of RNA interference and powerful tools of molecular genetics , it is particularly appealing to use T. castaneum for the dissection of insect immune pathways. Acquired knowledge may be useful in controlling beetle pests that feed on crop plants or stored products.
In the broader field of beetle immunity, research has been focused mainly on two effector mechanisms, namely antimicrobial peptide synthesis and prophenoloxidase (proPO) activation . Defensins, coleoptericins, cecropin and antifungal peptides have been isolated from coleopteran insects and characterized biochemically [10–12]. A homolog of human NF-κB (Allomyrina dichotoma Rel A) up-regulates the transcription of a coleoptericin gene . Active phenoloxidase generates quinones for melanin formation, wound healing, and microbe killing. ProPO activation has been investigated in Holotrichia diomphalia [14–16]. ProPO activating factor 1 (Hd-PPAF1) cleaves proPO to generate active phenoloxidase in the presence of Hd-PPAF2, the precursor of which is activated by Hd-PPAF3 via limited proteolysis. While all these PPAFs contain an amino-terminal clip domain, PPAF2 (in contrast to PPAF1 or PPAF3) does not have catalytic activity since its carboxy-terminal serine proteinase-like domain lacks the active site serine. A 43 kDa inhibitor down-regulates the melanization response in H. diomphalia .
To date, components of the innate immune system are hardly known in T. castaneum and neither is it clear how they differ from homologous molecules in the honeybee, mosquito or fruitfly [6, 7, 18]. This lack of knowledge does not seem to reconcile with the critical phylogenetic position of this coleopteran species, which should inform us a lot about genetic variations in the evolution of holometabolous insects. Information regarding defense responses in T. castaneum, a member of the largest and most diverse order of eukaryotes, is highly desirable for the biological control of crop pests and disease vectors. Consequently, we have used its newly available genome assembly to annotate immunity-related genes and analyze their phylogenetic relationships with homologous sequences from other insects. In this comparative overview of the Tribolium defense system, we describe plausible immune pathway models and present information regarding the molecular evolution of innate immunity in holometabolous species.
Results and discussion
Overview of the Triboliumimmune system
T. castaneum has a sizable repertoire of immune proteins predicted to participate in various humoral and cellular responses against wounding or infection (Additional data file 1). Like other insects [6, 7, 19], cuticle and epithelia lining its body surfaces, tracheae and alimentary tract may serve as a physiochemical barrier and local molecular defense by producing antimicrobial peptides and reactive oxygen/nitrogen species (ROS/RNS). While this line of defense may block most pathogens, others enter the hemocoel where a coordinated acute-phase reaction could occur to immobilize and kill the opportunists. This reaction, including phagocytosis, encapsulation, coagulation and melanization, is probably mediated by hemocytes and molecules constitutively present in the circulation. These first responders may not only control minor infections but also call fat body and hematopoietic tissues for secondary responses if necessary. At the molecular level, the following events should take place in all insects, including the beetle: recognition of invading organisms by plasma proteins or cell surface receptors, extra- and intracellular signal transduction and modulation, transcriptional regulation of immunity-related genes, as well as controlled release of defense molecules.
Peptidoglycan recognition proteins (PGRPs) serve as an important surveillance mechanism for microbial infection by binding to Lys- and diaminopimelate-type peptidoglycans of walled bacteria . Some Drosophila PGRPs (for example, LC and SA) are responsible for cell-mediated or plasma-based pathogen recognition; others (that is, LB and SB) may hydrolyze peptidoglycans to turn on/off immune responses [21, 22]. In T. castaneum, PGRP-LA, -LC and -LD contain a transmembrane segment; PGRP-SA and -SB are probably secreted; PGRP-LE (without a signal peptide or transmembrane region) may exist in cytoplasm or enter the plasma via a nonclassical secretory pathway. Bootstrap analysis and domain organization clearly indicate that Tribolium and Drosophila PGRP-LEs are orthologs - so far no PGRP-LE has been identified in Anopheles, Bombyx or Apis. Other orthologous relationships (for example, TcPGRP-LC and AmPGRP-LC) are also supported by the phylogenetic analysis (Figure 1). The beetle and mosquito PGRP-LA genes encode two alternative splice forms (PGRP-LAa and -LAb). Like Drosophila and Anopheles, Tribolium PGRP-LA and -LC genes are next to each other in the same cluster. Most of the beetle PGRPs resulted from ancient family diversification that occurred before the emergence of holometabolous insects. In contrast, gene duplication occurred several times in the lineages of mosquito and fly (Figure 1).
Multiple sequence alignment suggests that β-1,3-glucan-recognition proteins (β GRPs) and Gram-negative binding proteins (GNBPs) are descendents of invertebrate β-1,3-glucanases . Lacking one or more of the catalytic residues, these homologous molecules do not possess any hydrolytic activity. They are widespread in arthropods and act in part to recognize microbial cell wall components such as β-1,3-glucan, lipoteichoic acid or lipopolysaccharide. We have identified three β GRPs in T. castaneum. Tc-β GRP1 and AgGNBP-B1 through -B5 are closely related and represent a young lineage, whereas Tc-β GRP2 and Tc-β GRP3 belong to an ancient group that arose before the radiation of holometabolous insects (Additional data file 2). Since Drosophila has no β GRP-B and Anopheles has five, the presence of a single gene (encoding Tc-β GRP1) in the beetle can be useful for elucidating function of this orthologous group. In addition to the glucanase-like domain, members of the second group contain an amino-terminal extension of about 100 residues. In Bombyx mori β GRP, this region recognizes β-1,3-glucan also . M. sexta β GRP2 binds to insoluble β-1,3-glucan and triggers a serine proteinase cascade for proPO activation .
C-type lectins (CTLs) comprise a wide variety of soluble and membrane-bound proteins that associate with carbohydrates in a Ca2+-dependent manner . Some insect CTLs recognize microorganisms and enhance their clearance by hemocytes . Gene duplication and sequence divergence, particularly in the sugar-interacting residues, lead to a broad spectrum of binding specificities for mannose, galactose and other sugar moieties. These proteins associate with microbes and hemocytes to form nodules  and stimulate melanization response . T. castaneum encodes sixteen CTLs: ten (Tc-CTL1, 2, 4 through 10, and 13) with a single carbohydrate recognition domain and one (Tc-CTL3) with two. Five other proteins, tentatively named Tc-CTL11, 12, 14, 15 and 16, contain a CTL domain, a transmembrane region (except for Tc-CTL11), and other structural modules: CTL11 has three CUB and three EGF; CTL12 has six Ig and three FN3; CTL14 has one LDLrA, three CUB, ten Sushi, nineteen EGF, two discoidin, one laminin G and one hyalin repeat; CTL15 has one FTP, eleven Sushi and two EFh; CTL16 has one FTP and four Sushi. While lineage-specific expansion of the gene family is remarkable in D. melanogaster and A. gambiae , we have not found any evidence for that in T. castaneum (or A. mellifera): Tc-CTL1, 2, 5, 6, 8, 9, 12 through 16 have clear orthologs in the other insect species whereas Tc-CTL7, 10 and 11 are deeply rooted (Additional data file 3).
Galectins are β-galactoside recognition proteins with significant sequence similarity in their carbohydrate-binding sites characteristic of the family. Drosophila DL1 binds to E. coli and Erwinia chrysanthemi . Leishmania uses a sandfly galectin as a receptor for specific binding to the insect midgut . Tc-galectin1 has two carbohydrate recognition domains; Tc-galectin2 and 3 are orthologous to Am-galectin1 and 2, respectively (Additional data file 4).
All fibrinogen-related proteins (FREPs) contain a carboxy-terminal fibrinogen-like domain associated with different amino-terminal regions. In mammals, three classes of FREPs have been identified: ficolin, tenascins, and microfibril-associated proteins . They take part in phagocytosis, wound repair, and cellular adhesion . In invertebrates, FREPs are involved in cell-cell interaction, bacterial recognition, and antimicrobial responses [34–36]. The Tribolium genome contains seven FREP genes, which fall into three groups (Additional data file 5): the expansion of group I yielded four family members: Tc-FREP1 through 4. Sitting next to each other on chromosome 3, these beetle genes encode polypeptides most similar to angiopoietin-like proteins. During angiogenesis, the human plasma proteins interact with tyrosine kinase receptors (for example, Tie) and lead to wound repair and tissue regeneration . In group II, Tc-FREP5 is orthologous to Dm-scabrous, which is required for Notch signaling during tissue differentiation . Interestingly, Notch is also needed for proper differentiation of Drosophila hemocytes . Group III includes Tc-FREP6, Tc-FREP7, Ag-FREP9 and Dm-CG9593. No major expansion has occurred in the beetle or honeybee, in sharp contrast to the situations in the fly and mosquitoes - there are 61 FREP genes in the A. gambiae genome .
Thioester-containing proteins (TEPs), initially identified in D. melanogaster , contain a sequence motif (GCGEQ) commonly found in members of the complement C3/α 2-macroglobulin superfamily. After cleavage activation, some TEPs use the metastable thioester bond between the cysteine and glutamine residues to covalently attach to pathogens and 'mark' them for clearance by phagocytosis . One of the 15 TEPs in Anopheles, Ag-TEP1, plays a key role in the host response against Plasmodium infection and ten other Ag-TEPs are results of extensive gene duplications. This kind of family expansion did not happen in the beetle (or bee): Tribolium encodes four TEPs, perhaps for different physiological purposes. Our phylogenetic analysis supports the following orthologous relationships: TcA-AmA-Ag13-Dm6, TcB-AmB-Ag15-Dm3, and TcC-AmC (Additional data file 6).
Extracellular signal transduction and modulation
Similar to the alternative and lectin pathways for activation of human complements, insect plasma factors play critical roles in pathogen detection, signal relaying/tuning, and execution mechanisms. Serine proteinases (SPs) and their noncatalytic homologs (SPHs) are actively involved in these processes. Some SPs are robust enzymes that hydrolyze dietary proteins; others are delicate and specific - they cleave a single peptide bond in the protein substrates. The latter interact among themselves and with pathogen recognition proteins to mediate local responses against nonself. The specificity of such molecular interactions could be enhanced by SPHs, adaptor proteins that lack proteolytic activity due to substitution of the catalytic triad residues. SPs and SPHs constitute one of the largest protein families in insects [29, 41, 42]. We have identified 103 SP genes and 65 SPH genes in the Tribolium genome, 77 of which encode polypeptides with a SP or SP-like domain and other structural modules. These include thirty SPs and eighteen SPHs containing one or more regulatory clip domains. Clip-domain SPs, and occasionally clip-domain SPHs, act in the final steps of arthropod SP pathways . Other recognition/regulation modules (for example, LDLrA, Sushi, CUB and CTL) also exist in long SPs (>300 residues), some of which act in the beginning steps of SP pathways.
T. castaneum clip-domain proteins are divided into four subfamilies (Figure 2). Even though the catalytic or proteinase-like domains used for comparison were similar in length and sequence, we found subfamily A is composed of SPHs solely whereas subfamilies B, C and D comprise SPs mainly. Apparently, it is easier for SPs to lose activity and become SPHs during evolution than for SPHs to regain catalytic activity. The four groups of SP-related genes may represent lineages derived from ancient evolutionary events since similar subfamilies also exist in Anopheles and Drosophila. Moreover, expansion of individual subfamilies must have occurred several times to account for the gene clusters observed in the Tribolium genome (Figure 2). Evidence for lineage-specific gene duplication and movement is also present in the mosquito and fly genomes [29, 41]. Based on the results of genetic/biochemical analysis performed in other insects [14–16, 19, 44, 45] and sequence similarity, we are able to predict the physiological functions for some Tribolium clip-domain SPs and SPHs during proPO activation and spätzle processing. For instance, Tc-SPH2, SPH3 or SPH4 (similar to Hd-PPAF2) may serve as a cofactor for Tc-SP7, SP8 or SP10 (putative proPO activating proteinases); Tc-SP44 or SP66 may function like Drosophila persephone ; Tc-SP136 or SP138 may activate spätzle precursors by limited proteolysis [44, 45].
Most members of the serpin superfamily are irreversible inhibitors of SPs and, by forming covalent complexes with diffusing proteinases, they ensure a transient, focused defense response . There are totally 31 serpin genes in T. castaneum, more than that in D. melanogaster (28), A. gambiae (14) or A. mellifera (7). This number increase is mainly caused by a recent family explosion at a specific genomic location - we have identified a cluster of 16 serpin genes in a small region of 50 kilobases on chromosome 8. These closely related genes constitute a single clade in the phylogenetic tree (Figure 3). Sequence divergence, especially in the reactive site loop region, is anticipated to alleviate the selection pressure imposed by the SP family expansion (Figure 2). Exon duplication and alternative splicing, found in 4 of the 31 serpin genes, also generate sequence diversity and inhibitory selectivity.
Intracellular signal pathways and their regulation
Drosophila Toll is a transmembrane protein that binds spätzle and relays developmental and immune signals . Resulting from ancient family expansion, a total of five spätzle homologs and eight Toll-like receptors are present in the fly. There are seven Tribolium genes coding for spätzle-like proteins, most of which have putative orthologs in Drosophila and Anopheles (Additional data file 7). Like their ligands, Toll-like proteins have also experienced major family expansion and sequence divergence. The receptors are separated into two clusters, with the fly and beetle Toll-9 located near the tree center (Figure 4). While Toll-6, -7, -8 and -10 from different insect species constitute tight orthologous groups in one cluster, lineage-specific gene duplications have given rise to Drosophila Toll-3 and -4, Anopheles Toll-1 and -5, as well as Tribolium Toll-1 through -4. Located on the same branch with Drosophila Toll, the four Tribolium receptors could play different yet complementary roles in the beetle defense and development. In addition, we have identified eight MD2-related genes in the beetle. Mammalian MD2, Toll-like receptor-4 and CD14 form a complex that recognizes lipopolysaccharides . The Anopheles MD2-like receptor regulates the specificity of resistance against Plasmodium berghei .
Contrary to the ligand-receptor diversification, components of the intracellular pathway appear to be highly conserved in insects studied so far (Figure 5a). In Drosophila, multimerization of Toll receptors caused by spätzle binding leads to the association of dMyD88, Tube, Pelle, Pellino and dTRAF6 . With 1:1 orthologs identified in the beetle (as well as the other insects with known genomes), we postulate that a similar protein complex also forms to phosphorylate a cactus-like molecule (Tc02003). The modified substrate protein then dissociates from its partner (Tc07697 or Tc0896), allowing the Rel transcription factors to translocate into the nucleus and activate effector genes (for example, antimicrobial peptides). Functional tests are required to verify the suggested roles of individual components during defense and development in the beetle.
The IMD pathway is critical for fighting certain Gram-negative bacteria in Drosophila. Upon recognition of diaminopimelate-peptidoglycan by PGRPs, the 'danger' signal is transduced into the cell through IMD (Figure 5b). IMD contains a death domain that recruits dFADD (dTAK1 activator) and Dredd (a caspase). Active dTAK1 is a protein kinase that triggers the JNK pathway (through Hep, Basket, Jra and Kay) and Relish phosphorylation (through Ird5 and Kenny). The presence of 1:1 orthologs in T. castaneum strongly suggests that IMD-mediated immunity is conserved in the beetle. Furthermore, the modulation of these pathways may also resemble each other - we have identified putative 1:1 orthologs of IAP2, Tab2 and caspar in the Tribolium genome (Figure 5b).
The transcription of Drosophila TEPs and some other immune molecules is under the control of the JAK-STAT pathway . This pathway, triggered by a cytokine-like molecule, Upd3, promotes phagocytosis and participates in an antiviral response. Based on sequence similarity, we predict that the conserved signaling pathway in the beetle is composed of the orthologs of Dm-Domeless, Hopscotch and STAT92 (Figure 5c). However, we have not identified any ortholog of Dm-upd, upd2, or upd3, possibly due to high sequence variation in the cytokine-like proteins.
Phenoloxidases are copper-containing enzymes involved in multiple steps of several immune responses against pathogens and parasites (that is, clot reinforcement, melanin formation, ROS/RNS generation, and microbe killing) . Synthesized and released as an inactive zymogen, proPO requires a SP cascade for its cleavage activation. SPHs and serpins ensure that the proteolytic activation occurs locally and transiently in response to infection. We have identified three proPO genes in the Tribolium genome, designated proPO1, 2 and 3. Tc-proPO2 and proPO3 are 98.8% identical in nucleotide sequence and 99.6% identical in amino acid sequence. In the aligned coding regions (2,052 nucleotides long), 21 of the 24 substitutions are synonymous, corresponding to 0.0102 changes/site. These two genes are 530 kb apart and their aligned intron regions are 88.5% identical. Using the relative rate of nucleotide substitutions derived from an analysis of Drosophila alcohol dehydrogenase genes , we estimate that Tc-proPO2 and Tc-proPO3 arose by gene duplication approximately 0.6 million years ago. The phylogenetic analysis suggests that such evolutionary events are sporadic for this family: the total numbers of proPO genes in different insect species did not change significantly, except for the malaria mosquito (Additional data file 8). Of the nine Ag-proPO genes, eight arose from gene expansion that occurred early in the mosquito lineage , some of which encode phenoloxidases for melanization.
Local production of free radicals is a critical component of the acute-phase oxidative defense, involving nitric oxide synthase, NADPH oxidase, peroxidase, phenoloxidase and other enzymes [53, 55]. Due to the cytotoxicity of ROS and RNS, their conversion and concentrations must be tightly regulated by superoxide dismutases (SODs), glutathione oxidases (GTXs), catalases, thioredoxins, thioredoxin reductases, melanin intermediates, and certain metal ions. Changes in the free radical levels by gene mutation or knock-down affect the fecundity and antimalarial response of the mosquito . We have annotated some of these genes in Tribolium, including peroxidases, GTXs, SODs, peroxiredoxins (TPXs) and catalases. T. castaneum GTX1-GTX2 and TPX2-TPX6 gene pairs are results of recent gene duplications, whereas several orthologous relationships have been identified in the SOD and TPX families in the phylogenetic analysis (Additional data file 9).
Coleopteran species have been explored at the biochemical level for various antimicrobial peptides (AMPs) . While defensins are present in all insects studied, coleoptericins are related to the attacin/diptericin family of glycine-rich antibacterial peptides in lepidopteran and dipteran species . Four defensin genes are detected in the Tribolium genome, three of which are found in a branch containing only coleopteran insects (Figure 6). Tc-defensin4 is in a miscellaneous group containing Odonata, Lepidoptera and Arachnida species. Interestingly, defensins of three other coleopteran insects are in the same branch with the hymenopteran ones. Like the beetle defensins, coleoptericins belong to two phylogenetic groups, with the same separation of species in each group.
With the genome sequence available, we are able to use the other AMP sequences to identify homologous genes that are not specified in beetles. Cecropins were mostly identified in moths and flies - there was only one report on cecropin from a coleopteran species, Acalolepta luxuriosa . In Tribolium, we find a single close homolog of the Acalolepta cecropin, although a frame shift in a run of seven adenosines indicate that this is a pseudogene (Tc00499). Closely linked to Tc00499 on chromosome 2 are two genes that encode cecropin-related peptides of unusual structure, with proline- and tyrosine-rich carboxy-terminal extensions (Tc-cecropin2 and Tc00500). These observations indicate that cecropins may widely exist in beetles. Attacins were found only in lepidopteran and dipteran species. We have identified a cluster of three attacin genes (Tc07737-07739) on Tribolium chromosome 4. Although we failed to identify a Drosomycin homolog in the beetle, our search resulted in a low-score hit of a cysteine-rich sequence. The corresponding gene (Tc11324) encodes a 104 residue polypeptide containing 2 whey acidic protein motifs. While mammalian proteins with this motif possess antibacterial activities , expression and biochemical analyses are needed to test if the Tribolium protein has a similar function. Due to the presence of species-specific AMPs and severe sequence diversity of these molecules, our homology-based search has probably missed some AMP genes. Should there be a thorough exploration by sequence similarity, biochemical separation and activity assays (not only against Gram-positive and Gram-negative bacteria, but also against yeasts and filamentous fungi), we expect the total number of AMPs (currently 12) in T. castaneum may approach that (20) in D. melanogaster. In addition to these, we have found a cluster of four lysozyme genes in the Tribolium genome (Additional data file 10). Similar but independent family growths have occurred in different insect groups, giving rise to thirteen such genes in Drosophila, eight in Anopheles, three in Apis, and four in Tribolium.
Cellular responses (that is, phagocytosis, nodulation and encapsulation) play key roles in the insect innate immunity . In the past few years, breakthroughs have been made in the molecular dissection of these processes . Drosophila Peste, Eater, scavenger receptor (SR)-CI, Dscam, TEPs, and PGRP-SC1a seem to be implicated in the phagocytosis. Multiple SR-B genes are present in the Tribolium (16), Drosophila (12) and Anopheles (16) genomes, indicative of important functions of the subfamily. A phylogenetic analysis of the SR-Bs (Figure 7) demonstrates that nearly half of the members arose from ancient gene duplication events - we can easily identify orthologs from different insect species. More recent family expansions in the mosquito  and beetle account for the other half of the subfamily. There are two SR-B gene clusters in the Tribolium genome, one of which (TcSR-B14, -B15 and -B16) is located in the same branch containing Dm-peste. In addition to SR-Bs, Drosophila Nimrods are also involved in cellular responses . The plasmatocyte-specific NimC1 directly participates in the phagocytosis of bacteria. For Tribolium, all three subclasses are represented: NimA, NimB and NimC, just like in the fly, mosquito and bee. However, unlike the other insects, the syntenic relationship is broken up in the beetle NimC homologs: the two NimC paralogs (Tc02053 and Tc15258) are not closely linked to the NimA and NimB homologs (Tc11427 and Tc11428). In the other insects, the order of nimA, nimB and nimC genes is well conserved.
One characteristic of the innate immune system is that some of its components are transcriptionally up-regulated after a microbial challenge. To acquire evidence that the genes we annotated are involved in defense responses, we have exposed the adult beetles to E. coli, Micrococcus luteus, Candida albicans or Saccharomyces cerevisiae cells and isolated total RNA from the control and treated insects for expression analysis. Real-time PCR experiments indicated that transcript levels of some genes dramatically changed (Figure 8). TcPGRP-SA and TcPGRP-SB mRNA became more abundant after the bacterial infection, whereas the increase was much less significant for TcPGRP-LA, -LE, galectin1 or TEP-C after the C. albicans or M. luteus treatment. Following the Gram-positive bacterial or fungal challenge, we detected some elevations in Tc-cSP66, serpin29 and serpin30 transcripts.
Transcriptional regulation is not limited to pattern recognition molecules or extracellular signal mediators/modulators: we detected differential expression of ligand and their receptors (for example, Tc-spätzle1, Toll-1 through Toll-4, and IMD). mRNA level changes for the latter genes were small except for IMD (Figure 8). Toll-3 and Toll-4 induction after the C. albicans or M. luteus challenge was apparent, although not as notable as IMD. The subtle changes in Toll-1 transcript levels were somewhat different from those of Toll-2, -3 and -4, indicating that there could be functional differences and overlaps in antimicrobial responses for these closely related receptors (Figure 4).
We have also examined genes whose products are plasma proteins directly involved in microbe immobilization or killing. The transcripts of Tc-proPOs, lysozyme1 or lysozyme4 did not significantly change when compared with the controls, whereas those of Tc-lysozyme2 and 3 increased remarkably (Figure 8). The most dramatic increase in mRNA levels occurred in the AMP group of effector molecules, including Tc-attacin2, cecropin3, coleoptericin1, defensin1, and defensin2.
Cluster analysis of the expression patterns has revealed several trends of the transcriptional control of these immune genes. Buffer injected and uninjured adults form one cluster with the lowest mRNA levels, whereas E. coli- and S. cerevisiae-treated insects have the next higher level of overall gene expression (Figure 8). The yeast-injected beetles, instead of grouping with E. coli-treated insects, are found in the same cluster with C. albicans-challenged adults. Interestingly, immune responses toward the opportunistic fungal pathogen are greater than those toward S. cerevisiae, an environmental non-pathogen present in the diet. The responses toward M. luteus and C. albicans were significantly stronger than those towards E. coli, implying that the Toll pathway triggered by the Gram-positive bacteria and filamentous fungi more effectively up-regulated target gene expression than the IMD pathway did, which may be activated by the Gram-negative bacterial infection (Figure 5).
Through this comparative genome analysis, we have provided evidence in the red flour beetle for the functional conservation of intracellular immune signaling pathways (Toll, IMD and JAK/SAT) and for the evolutionary diversification of over 20 families of proteins (for example, PGRPs, clip-domain proteins, serpins, Toll-related receptors, antimicrobial proteins and scavenger receptors) involved in different mechanisms of insect defense against infection. The observed differences in conservation are likely related to distinct needs for specific molecular interactions and changes in microorganisms encountered by the host insects. For instance, Drosophila Myd88, Tube, Pelle, Pellino and TRAF, which form a macromolecular complex with the Toll/interleukin 1 receptor domain (Figure 5), have 1:1 orthologs in Anopheles, Apis and Tribolium. In contrast, family expansion and sequence divergence in the PGRP and AMP families are perhaps important for specific recognition and effective elimination of evolving pathogens.
The summary of putative immune gene counts, families and functions (Additional data file 11) suggests that T. castaneum has a more general defense than A. gambiae does. While this system is critical for the survival of this beetle, we are unclear whether or not it correlates with the prosperity of coleopteran insects. Drastic lineage-specific expansions seem sporadic and, in most cases, Tribolium paralog counts are lower than those of Anopheles or Drosophila (but are considerably higher than of Apis). The only exceptions are the clip-domain SP/SPH and serpin families: 48, 41 and 37 proteinase-related genes and 31, 14 and 28 inhibitor genes are present in the beetle, mosquito and flies, respectively. Because clip-domain SPs are often regulated by serpins, positive selection may have played a role in the converted evolution of both families and in the maintenance of homeostasis.
This comparative analysis has also uncovered interesting genes and gene families for future research. For instance, the existence of a 1:1 ortholog of Drosophila PGRP-LE in Tribolium (but not in Anopheles or Apis) may allow us to test whether or not TcPGRP-LE has a similar function. It can be interesting to explore the molecular mechanisms and evolutionary pathways of the large serpin and SP gene clusters in the beetle. The presence of TcToll-1 through -4 and subtle changes in their mRNA levels after immune challenges call for detailed analysis of their transcriptional regulation and physiological functions. Of course, the proposed extracellular and intracellular signaling pathways need to be tested, even though we have confidence in their general structures. The possible AMP function of Tc11324, which contains two whey acidic protein motifs, needs to be established experimentally.
It is noteworthy that the functions of Tribolium immunity-related genes are mostly assumed based on sequence similarity to studied proteins in Drosophila or other insect species. Functional analyses using the strong reverse genetic techniques available in Tribolium are necessary to test the hypotheses. Nevertheless, the framework of information established in this work should help clarify immune functions in an important agricultural pest from the most diverse insect order and a species that can serve as a tractable model for an innate immune system more generally.
Materials and methods
Database search and sequence annotation
Known defense proteins from other insects were used as queries to perform BLASTP searches of Tcastaneum Glean Predictions (2005.10.11) . Protein sequences with E-values lower than 0.1 were listed, and every 5th sequence was retrieved for use as a query for another round of search. Based on the combined lists, respective protein sequences were retrieved, compiled in the order of ascending E-values, and improved by two methods. Firstly, Tcastaneum ESTs (2005.9.20) at the same HGSC site were searched with the corresponding nucleotide sequences to identify possible cDNA clones. The EST sequences were assembled using CAP3  and the resulting contigs were used in pairwise comparison  to validate the gene predictions. Secondly, retrieved protein sequences were analyzed by CDART , PROSITE , and SMART  to detect conserved domain structures required for specific functions. Necessary changes were made after each step to improve the original predictions. Chromosomal location and exon-intron boundaries for each annotated sequence were acquired from Genboree . To locate orthologs not identified by BLASTP, Tribolium Genome Assembly 2.0  was searched using TBLASTN. The hits detected were analyzed using multiple gene prediction tools Genescan and Genemark [71, 72]. All curated sequences then were deposited in the annotation database  as a part of Tribolium Genome Assembly 2.0.
Unless otherwise specified, full-length Tribolium sequences were aligned with their homologs from other insects, including D. melanogaster, A. gambiae and A. mellifera. The sequences were retrieved from NCBI , Flybase , or Ensembl . Multiple sequence alignments were carried out using ClustalX  and Blosum series of weight matrices . Phylogenetic trees were constructed based on algorithm of neighbor-joining using PHYLIP  or maximum-parsimony using PAUP . The divergence time of Tc-proPO2 and proPO3 were calculated using the rate of 1.7 × 10-8 synonymous substitutions/nucleotide/year derived from the Drosophila species .
Gene expression analysis
To study pathogen-induced gene expression, adult red flour beetles (approximately 240 per group) were pricked at the ventral thorax with needles dipped in sterile phosphate-buffered saline or the buffer containing concentrated live E. coli, M. luteus, C. albicans or S. cerevisiae cells. Uninjured and aseptically injured insects were employed as controls. Total RNA samples were extracted from the control and challenged insects (approximately 160 per group) 24 h later, using Micro-to-mid RNA Purification System (Invitrogen, Carlsbad, CA, USA). After DNA removal, each RNA sample (1.0-3.4 μg), oligo(dT) (0.5 μg, 1 μl) and dNTPs (10 mM each, 1 μl) were mixed with diethyl pyrocarbonate-treated H2O in a final volume of 12 μl, and denatured at 65°C for 5 minutes. First strand cDNA was synthesized for 50 minutes at 42°C using SuperScript Reverse Transcriptase (200 U/μl, 1 μl; Invitrogen) mixed with 5 × buffer (4 μl), 0.1 M dithiothreitol (2 μl), RNase OUT (40 U/μl, 1 μl; Invitrogen) and the denatured RNA sample (12 μl). Specific primer pairs were designed for a total of 35 immunity-related genes (Additional data file 12) using Primer 3  with annealing temperatures of 59.5-60.5°C and expected product sizes of 80-150 bp. Each primer pair was located in adjacent exons flanking an intron. Real-time PCR was performed in parallel reactions on 96-well microtiter plates using Taq DNA polymerase (1 U; Roche Applied Sciences, Indianapolis, IN, USA), 1 × buffer, 1 mM dNTP mix, 2 mM MgCl2, 0.2 μM primers, 1 × SYBR-Green I dye (Applied Biosystems, Foster City, CA, USA) and 10 nM fluorescein. Amplifications were enacted on an iCycler thermal cycler (Bio-Rad, Hercules, CA, USA) with a profile of 95°C for 5 minutes followed by 40 cycles of 94°C for 20 s, 60°C for 30 s, 72°C for 60 s and 78°C for 20 s . SYBR green fluorescence was measured during the 78°C step in each cycle and the cycle numbers for each target and control gene were recorded when the fluorescence passed a predetermined threshold. Proper dissociation and correct size of the products were examined by melting curve analysis and agarose gel electrophoresis, respectively. The real-time PCR was repeated twice and, in each of the three experimental replicates, the transcripts were normalized relative to the levels of Tribolium ribosomal protein S3. Averaged transcript abundance values (Ctcontrol - Cttarget) were then compared across genes and samples using average-linking clustering (Cluster 3.0) and visualized using TreeView .
Additional data files
The following additional data are available with the online version of this paper. Additional data file 1 is a table listing immunity-related genes in T. castaneum. Additional data file 2 is a figure showing sequence alignments of βGRPs and GNBPs. Additional data file 3 is a figure showing sequence alignments of CTLs. Additional data file 4 is a figure showing sequence alignments of galectins. Additional data file 5 is a figure showing sequence alignments of FREPs. Additional data file 6 is a figure showing sequence alignments of TEPs. Additional data file 7 is a figure showing sequence alignments of Spätzle-related proteins. Additional data file 8 is a figure showing sequence alignments of proPOs. Additional data file 9 is a figure showing sequences of GTX, SOD and TPX. Additional data file 10 is a figure showing sequence alignments of lysozymes. Additional data file 11 is a table listing functions, families, and counts of putative defense proteins from D. melanogaster, A. gambiae, A. mellifera and T. castaneum. Additional data file 12 is a table listing oligonucleotide primers used in expression analysis by real-time PCR.
- β GRP:
Gram-negative binding protein
peptidoglycan recognition protein
proPO activating factor
reactive nitrogen species
reactive oxygen species
noncatalytic serine proteinase homolog
Wade MJ, Chang NW: Increased male-fertility in Tribolium confusum beetles after infection with the intracellular parasite Wolbachia. Nature. 1995, 373: 72-74. 10.1038/373072a0.
Blaser M, Schmid-Hempel P: Determinants of virulence for the parasite Nosema whitei in its host Tribolium castaneum. J Invertebr Pathol. 2005, 89: 251-257. 10.1016/j.jip.2005.04.004.
Zhong D, Pai A, Yan G: Costly resistance to parasitism: evidence from simultaneous quantitative trait loci mapping for resistance and fitness in Tribolium castaneum. Genetics. 2005, 169: 2127-2135. 10.1534/genetics.104.038794.
Moret Y: "Trans-generational immune priming": specific enhancement of the antimicrobial immune response in the mealworm beetle, Tenebrio molitor. Proc Biol Sci. 2006, 273: 1399-1405. 10.1098/rspb.2006.3465.
Arakane Y, Muthukrishnan S, Beeman RW, Kanost MR, Kramer KJ: Laccase 2 is the phenoloxidase gene required for beetle cuticle tanning. Proc Natl Acad Sci USA. 2005, 102: 11337-11342. 10.1073/pnas.0504982102.
Lemaitre B, Hoffmann J: The host defense of Drosophila melanogaster. Annu Rev Immunol. 2007, 25: 697-743. 10.1146/annurev.immunol.25.022106.141615.
Christophides GK, Vlachou D, Kafatos FC: Comparative and functional genomics of the innate immune system in the malaria vector Anopheles gambiae. Immunolog Rev. 2004, 198: 127-148. 10.1111/j.0105-2896.2004.0127.x.
Brown SJ, Denell RE, Beeman RW: Beetling around the genome. Genetical Res. 2003, 82: 155-161. 10.1017/S0016672303006451.
Iwanaga S, Lee BL: Recent advances in the innate immunity of invertebrate animals. J Biochem Mol Biol. 2005, 38: 128-150.
Barbault F, Landon C, Guenneugues M, Meyer JP, Schott V, Dimarcq JL, Vovelle F: Solution structure of Alo-3: a new knottin-type antifungal peptide from the insect Acrocinus longimanus. Biochemistry. 2003, 42: 14434-14442. 10.1021/bi035400o.
Saito A, Ueda K, Imamura M, Atsumi S, Tabunoki H, Miura N, Watanabe A, Kitami M, Sato R: Purification and cDNA cloning of a cecropin from the longicorn beetle, Acalolepta luxuriosa. Comparative Biochem Physiol B Biochem Mol Biol. 2005, 142: 317-323. 10.1016/j.cbpb.2005.08.001.
Bulet P, Cociancich S, Dimarcq JL, Lambert J, Reichhart JM, Hoffmann D, Hetru C, Hoffmann JA: Insect immunity. Isolation from a coleopteran insect of a novel inducible antibacterial peptide and of new members of the insect defensin family. J Biol Chem. 1991, 266: 24520-24525.
Sagisaka A, Tanaka H, Furukawa S, Yamakawa M: Characterization of a homologue of the Rel/NF-kappaB transcription factor from a beetle, Allomyrina dichotoma. Biochim Biophys Acta. 2004, 1678: 85-93.
Kim MS, Baek MJ, Lee MH, Park JW, Lee SY, Soderhall K, Lee BL: A new easter-type serine protease cleaves a masquerade-like protein during prophenoloxidase activation in Holotrichia diomphalia larvae. J Biol Chem. 2002, 277: 39999-40004. 10.1074/jbc.M205508200.
Kwon TH, Kim MS, Choi HW, Joo CH, Cho MY, Lee BL: A masquerade-like serine proteinase homologue is necessary for phenoloxidase activity in the coleopteran insect, Holotrichia diomphalia larvae. Eur J Biochem. 2000, 267: 6188-6196. 10.1046/j.1432-1327.2000.01695.x.
Lee SY, Kwon TH, Hyun JH, Choi JS, Kawabata SI, Iwanaga S, Lee BL: In vitro activation of pro-phenol-oxidase by two kinds of pro-phenol-oxidase-activating factors isolated from hemolymph of coleopteran, Holotrichia diomphalia larvae. Eur J Biochem. 1998, 254: 50-57. 10.1046/j.1432-1327.1998.2540050.x.
Zhao M, Soderhall I, Park JW, Ma YG, Osaki T, Ha NC, Wu CF, Soderhall K, Lee BL: A novel 43-kDa protein as a negative regulatory component of phenoloxidase-induced melanin synthesis. J Biol Chem. 2005, 280: 24744-24751. 10.1074/jbc.M504173200.
Evans JD, Aronstein K, Chen YP, Hetru C, Imler JL, Jiang H, Kanost M, Thompson GJ, Zou Z, Hultmark D: Immune pathways and defence mechanisms in honey bees Apis mellifera. Insect Mol Biol. 2006, 15: 645-656. 10.1111/j.1365-2583.2006.00682.x.
Kanost MR, Jiang HB, Yu XQ: Innate immune responses of a lepidopteran insect, Manduca sexta. Immunol Rev. 2004, 198: 97-105. 10.1111/j.0105-2896.2004.0121.x.
Steiner H: Peptidoglycan recognition proteins: on and off switches for innate immunity. Immunol Rev. 2004, 198: 83-96. 10.1111/j.0105-2896.2004.0120.x.
Kim MS, Byun MJ, Oh BH: Crystal structure of peptidoglycan recognition protein LB from Drosophila melanogaster. Nat Immunol. 2003, 4: 787-793. 10.1038/ni952.
Mellroth P, Karlsson J, Steiner H: A scavenger function for a Drosophila peptidoglycan recognition protein. J Biol Chem. 2003, 278: 7059-7064. 10.1074/jbc.M208900200.
Jiang HB, Ma CC, Lu ZQ, Kanost MR: β-1,3-Glucan recognition protein-2 (beta GRP-2) from Manduca sexta: an acute-phase protein that binds beta-1,3-glucan and lipoteichoic acid to aggregate fungi and bacteria and stimulate prophenoloxidase activation. Insect Biochem Mol Biol. 2004, 34: 89-100. 10.1016/j.ibmb.2003.09.006.
Ochiai M, Ashida M: A pattern-recognition protein for beta-1,3-glucan - The binding domain and the cDNA cloning of beta-1,3-glucan recognition protein from the silkworm, Bombyx mori. J Biol Chem. 2000, 275: 4995-5002. 10.1074/jbc.275.7.4995.
Wang Y, Jiang H: Interaction of beta-1,3-glucan with its recognition protein activates hemolymph proteinase 14, an initiation enzyme of the prophenoloxidase activation system in Manduca sexta. J Biol Chem. 2006, 281: 9271-9278. 10.1074/jbc.M513797200.
Vasta GR, Quesenberry M, Ahmed H, O'Leary N: C-type lectins and galectins mediate innate and adaptive immune functions: their roles in the complement activation pathway. Dev Comparative Immunol. 1999, 23: 401-420. 10.1016/S0145-305X(99)00020-8.
Koizumi N, Imamura M, Kadotani T, Yaoi K, Iwahana H, Sato R: The lipopolysaccharide-binding protein participating in hemocyte nodule formation in the silkworm Bombyx mori is a novel member of the C-type lectin superfamily with two different tandem carbohydrate-recognition domains. FEBS Lett. 1999, 443: 139-143. 10.1016/S0014-5793(98)01701-3.
Yu XQ, Kanost MR: Immulectin-2, a lipopolysaccharide-specific lectin from an insect, Manduca sexta, is induced in response to gram-negative bacteria. J Biol Chem. 2000, 275: 37373-37381. 10.1074/jbc.M003021200.
Christophides GK, Zdobnov E, Barillas-Mury C, Birney E, Blandin S, Blass C, Brey PT, Collins FH, Danielli A, Dimopoulos G, et al: Immunity-related genes and gene families in Anopheles gambiae. Science. 2002, 298: 159-165. 10.1126/science.1077136.
Tanji T, Ohashi-Kobayashi A, Natori S: Participation of a galactose-specific C-type lectin in Drosophila immunity. Biochem J. 2006, 396: 127-138. 10.1042/BJ20051921.
Kamhawi S, Ramalho-Ortigao M, Pham VM, Kumar S, Lawyer PG, Turco SJ, Barillas-Mury C, Sacks DL, Valenzuela JG: A role for insect galectins in parasite survival. Cell. 2004, 119: 329-341. 10.1016/j.cell.2004.10.009.
Fujita T, Endo Y, Nonaka M: Primitive complement system - recognition and activation. Mol Immunol. 2004, 41: 103-111. 10.1016/j.molimm.2004.03.026.
Litman GW, Cannon JP, Dishaw LJ: Reconstructing immune phylogeny: New perspectives. Nat Rev Immunol. 2005, 5: 866-879. 10.1038/nri1712.
Gokudan S, Muta T, Tsuda R, Koori K, Kawahara T, Seki N, Mizunoe Y, Wai SN, Iwanaga S, Kawabata S: Horseshoe crab acetyl group-recognizing lectins involved in innate immunity are structurally related to fibrinogen. Proc Natl Acad Sci USA. 1999, 96: 10086-10091. 10.1073/pnas.96.18.10086.
Schroder HC, Ushijima H, Krasko A, Gamulin V, Thakur NL, Diehl-Seifert B, Muller IM, Muller WEG: Emergence and disappearance of an immune molecule, an antimicrobial lectin, in basal Metazoa - A tachylectin-related protein in the sponge Suberites domuncula. J Biol Chem. 2003, 278: 32810-32817. 10.1074/jbc.M304116200.
Wang X, Rocheleau TA, Fuchs JF, Hillyer JF, Chen CC, Christensen BM: A novel lectin with a fibrinogen-like domain and its potential involvement in the innate immune response of Armigeres subalbatus against bacteria. Insect Mol Biol. 2004, 13: 273-282. 10.1111/j.0962-1075.2004.00484.x.
Morisada T, Kubota Y, Urano T, Suda T, Oike Y: Angiopoietins and angiopoietin-like proteins in angiogenesis. Endothelium J Endothelial Cell Res. 2006, 13: 71-79. 10.1080/10623320600697989.
Mok LP, Qin TL, Bardot B, LeComte M, Homayouni A, Ahimou F, Wesley C: Delta activity independent of its activity as a ligand of Notch. BMC Dev Biol. 2005, 5: 6-10.1186/1471-213X-5-6.
Williams MJ: Drosophila hemopoiesis and cellular immunity. J Immunol. 2007, 178: 4711-4716.
Lagueux M, Perrodou E, Levashina EA, Capovilla M, Hoffmann JA: Constitutive expression of a complement-like protein in Toll and JAK gain-of-function mutants of Drosophila. Proc Natl Acad Sci USA. 2000, 97: 11427-11432. 10.1073/pnas.97.21.11427.
Ross J, Jiang H, Kanost MR, Wang Y: Serine proteases and their homologs in the Drosophila melanogaster genome: an initial analysis of sequence conservation and phylogenetic relationships. Gene. 2003, 304: 117-131. 10.1016/S0378-1119(02)01187-3.
Zou Z, Lopez DL, Kanost MR, Evans JD, Jiang HB: Comparative analysis of serine protease-related genes in the honey bee genome: possible involvement in embryonic development and innate immunity. Insect Mol Biol. 2006, 15: 603-614. 10.1111/j.1365-2583.2006.00684.x.
Jiang HB, Kanost MR: The clip-domain family of serine proteinases in arthropods. Insect Biochem Mol Biol. 2000, 30: 95-105. 10.1016/S0965-1748(99)00113-7.
Tang H, Kambris Z, Lemaitre B, Hashimoto C: Two proteases defining a melanization cascade in the immune system of Drosophila. J Biol Chem. 2006, 281: 28097-28104. 10.1074/jbc.M601642200.
Jang IH, Chosa N, Kim SH, Nam HJ, Lemaitre B, Ochiai M, Kambris Z, Brun S, Hashimoto C, Ashida M, et al: A Spatzle-processing enzyme required for toll signaling activation in Drosophila innate immunity. Dev Cell. 2006, 10: 45-55. 10.1016/j.devcel.2005.11.013.
Ligoxygakis P, Pelte N, Hoffmann JA, Reichhart JM: Activation of Drosophila Toll during fungal infection by a blood serine protease. Science. 2002, 297: 114-116. 10.1126/science.1072391.
Kanost MR: Serine proteinase inhibitors in arthropod immunity. Dev Comparative Immunol. 1999, 23: 291-301. 10.1016/S0145-305X(99)00012-9.
Hultmark D: Drosophila immunity: paths and patterns. Curr Opin Immunol. 2003, 15: 12-19. 10.1016/S0952-7915(02)00005-5.
Miller SI, Ernst RK, Bader MW: LPS, TLR4 and infectious disease diversity. Nat Rev Microbiol. 2005, 3: 36-46. 10.1038/nrmicro1068.
Dong Y, Aguilar R, Xi Z, Warr E, Mongin E, Dimopoulos G: Anopheles gambiae immune responses to human and rodent Plasmodium parasite species. PLoS pathogens. 2006, 2: e52-10.1371/journal.ppat.0020052.
Wang LH, Ligoxygakis P: Pathogen recognition and signalling in the Drosophila innate immune response. Immunobiology. 2006, 211: 251-261. 10.1016/j.imbio.2006.01.001.
Agaisse H, Perrimon N: The roles of JAK/STAT signaling in Drosophila immune responses. Immunol Rev. 2004, 198: 72-82. 10.1111/j.0105-2896.2004.0133.x.
Nappi AJ, Christensen BM: Melanogenesis and associated cytotoxic reactions: Applications to insect innate immunity. Insect Biochem Mol Biol. 2005, 35: 443-459. 10.1016/j.ibmb.2005.01.014.
Rowan RG, Hunt JA: Rates of DNA change and phylogeny from the DNA-sequences of the alcohol-dehydrogenase gene for five closely related species of Hawaiian Drosophila. Mol Biol Evol. 1991, 8: 49-70.
Kumar S, Barillas-Mury C: Ookinete-induced midgut peroxidases detonate the time bomb in anopheline mosquitoes. Insect Biochem Mol Biol. 2005, 35: 721-727. 10.1016/j.ibmb.2005.02.014.
DeJong RJ, Miller LM, Molina-Cruz A, Gupta L, Kumar S, Barillas-Mury C: Reactive oxygen species detoxification by catalase is a major determinant of fecundity in the mosquito Anopheles gambiae. Proc Natl Acad Sci USA. 2007, 104: 2121-2126. 10.1073/pnas.0608407104.
Bulet P, Stocklin R, Menin L: Anti-microbial peptides: from invertebrates to vertebrates. Immunol Rev. 2004, 198: 169-184. 10.1111/j.0105-2896.2004.0124.x.
Hedengren M, Borge K, Hultmark D: Expression and evolution of the Drosophila Attacin/Diptericin gene family. Biochem Biophys Res Commun. 2000, 279: 574-581. 10.1006/bbrc.2000.3988.
Hagiwara K, Kikuchi T, Endo Y, Huqun , Usui K, Takahashi M, Shibata N, Kusakabe T, Xin H, Hoshi S, et al: Mouse SWAM1 and SWAM2 are antibacterial proteins composed of a single whey acidic protein motif. J Immunol. 2003, 170: 1973-1979.
Lavine MD, Strand MR: Insect hemocytes and their role in immunity. Insect Biochem Mol Biol. 2002, 32: 1295-1309. 10.1016/S0965-1748(02)00092-9.
Cherry S, Silverman N: Host-pathogen interactions in Drosophila: new tricks from an old friend. Nat Immunol. 2006, 7: 911-917. 10.1038/ni1388.
Kurucz E, Markus R, Zsamboki J, Folkl-Medzihradszky K, Darula Z, Vilmos P, Udvardy A, Krausz I, Lukacsovich T, Gateff E, et al: Nimrod, a putative phagocytosis receptor with EGF repeats in Drosophila plasmatocytes. Curr Biol. 2007, 17: 649-654. 10.1016/j.cub.2007.02.041.
Tcastaneum Glean Predictions. [http://www.hgsc.bcm.tmc.edu/blast.hgsc?organism=13]
Huang XQ, Madan A: CAP3: A DNA sequence assembly program. Genome Res. 1999, 9: 868-877. 10.1101/gr.9.9.868.
BLAST 2 Sequences. [http://0-www.ncbi.nlm.nih.gov.brum.beds.ac.uk/blast/bl2seq/wblast2.cgi]
Tribolium Genome Assembly 2.0. [ftp://ftp.hgsc.bcm.tmc.edu/pub/data/Tcastaneum/Tcas2.0/]
Annotation Database. [http://annotation.hgsc.bcm.tme.edu/]
Chenna R, Sugawara H, Koike T, Lopez R, Gibson TJ, Higgins DG, Thompson JD: Multiple sequence alignment with the Clustal series of programs. Nucleic Acids Res. 2003, 31: 3497-3500. 10.1093/nar/gkg500.
Henikoff S, Henikoff JG: Amino acid substitution matrices from protein blocks. Proc Natl Acad Sci USA. 1992, 89: 10915-10919. 10.1073/pnas.89.22.10915.
Evans JD: Beepath: An ordered quantitative-PCR array for exploring honey bee immunity and disease. J Invertebrate Pathol. 2006, 93: 135-139. 10.1016/j.jip.2006.04.004.
We greatly appreciate our colleagues in the Tribolium genome sequence consortium for the gene prediction. Dr Thomas Phillips kindly provided the insects for immune challenges and RT-PCR experiments. We would also like to thank Drs Ulrich Melcher, Jack Dillwith, and Maureen Gorman for their helpful comments on the manuscript. This work was supported by the National Institutes of Health Grants GM58634 (to HJ). The article was approved for publication by the Director of Oklahoma Agricultural Experimental Station and supported in part under project OKLO2450.
Zhen Zou: study design; data collection, analysis and deposition; annotation of clip-domain SPs/SPHs, serpins, spätzles, SRs and others; Toll and Imd pathways. Jay Evans: RT-PCR analysis; GNBPs and PGRPs. Zhiqiang Lu: C-type lectins, galectins, TEPs and JAK/STAT pathway. Picheng Zhao: Toll-like receptors, caspases and ROS/RNS production. Michael Williams and Dan Hultmark: FREPs, Nimrods, PGRPs and cecropins. Charles Hetru and Niranji Sumathipala: antimicrobial peptides and lysozymes. Haobo Jiang: study design; data analysis and interpretation; annotation of clip-domain SPs/SPHs; manuscript writing.
Zhen Zou and Haobo Jiang contributed equally to this work.
Electronic supplementary material
Additional data file 2: The sequences of three Tribolium (Tc), three Drosophila (Dm), two Apis (Am), six Anopheles (Ag) and two Bombyx βGRPs/GNBPs are aligned with Bacillus circulans (Bc) β-1,3-glucanase A1 as an outgroup. There was a family expansion in the lineage of A. gambiae. Pink arrowheads indicate nodes with bootstrap values greater than 800 from 1,000 trials, and the dashed line marks the outgroup. (PPT 26 KB)
Additional data file 3: The sequences of sixteen Tribolium (Tc), ten Drosophila (Dm), eight Anopheles (Ag) and eight Apis (Am) sequences are aligned. TcCTL3 (that is, Tc 3) contains two carbohydrate recognition domains and the first one is used for comparison. Different CTL subfamilies (GA, galactose; MA, mannose) are indicated, with the predicted orthologous groups marked by blue dots (for 1:1, 1:1:1 and 1:1:1:1 relationships). Pink arrowheads indicate nodes with significant bootstrap values (>800 of 1,000 trials). Note that many Dm- and Ag-CTLs, not included in this analysis, are results of major lineage-specific expansions . (PPT 58 KB)
Additional data file 4: The amino acid sequences from three Tribolium (Tc), seven Drosophila (Dm), seven Anopheles (Ag), two Apis (Am) and one Phlebotomus (Pp) galectins are examined. The phylogenetic tree, derived from the aligned sequences, shows family expansions in Anopheles (pink) and Drosophila (blue). Pink arrowheads at nodes denote bootstrap values greater than 800 from 1,000 trials. Green lines connect the putative orthologous pairs or trio. (PPT 40 KB)
Additional data file 5: The sequences of seven Tribolium (Tc), fourteen Drosophila (Dm), nine Anopheles (Ag), nine Aedes (Aa) and one Apis (Am) FREPs are aligned for constructing this unrooted tree. For simplicity, other family members from Drosophila, Anopheles and Aedes are excluded from the analysis. Lineage-specific expansions (shaded yellow for Tribolium, blue for Drosophila and pink for Anopheles) are confirmed in the complete tree that includes all FREPs from these four species (data not shown). Nodes with pink arrowheads have bootstrap values exceeding 800 in 1,000 trials. Green bars connect the putative orthologs with 1:1 or 1:1:1 relationship. The chromosomal locations (lower corner) of Tribolium FREP-1 through -4 are shown. (PPT 56 KB)
Additional data file 6: The sequences of four Tribolium (Tc), six Drosophila (Dm), fifteen Anopheles (Ag) and three Apis (Am) TEPs are aligned. Lineage-specific family expansions are indicated with color shades (blue for Drosophila and pink for Anopheles). Pink arrowheads at nodes denote bootstrap values greater than 800 for 1,000 trials, and green bars link the predicted 1:1 and 1:1:1:1 orthologs. (PPT 48 KB)
Additional data file 7: The amino acid sequences of seven Tribolium (Tc), six Drosophila (Dm), five Anopheles (Ag), two Apis (Am) and one Bombyx (Bm) spätzles are aligned for building the unrooted tree. Pink arrowheads indicate nodes with significant bootstrap values (>800 of 1,000 trials), and green bars connect the putative orthologous pairs or trios. (PPT 35 KB)
Additional data file 8: The entire sequences of Tribolium (Tc), Tenebrio (Tm), Holotrichia (Hd), and Drosophila (Dm), Anopheles (Ag), Apis (Am), Bombyx (Bm) and Manduca (Ms) proPOs are compared. Tribolium proPO3, >99% identical in amino acid sequence to Tc-proPO2, is not included in the analysis. The phylogenetic tree, derived from the multiple sequence alignment, shows the extensive family expansion (shaded pink) in the malaria mosquito. Pink arrowheads point to nodes with high bootstrap values (>800 from 1,000 trials), and green lines link the predicted 1:1 or 1:1:1 orthologs. (PPT 41 KB)
Additional data file 9: (a) GTX, (b) SOD and (c) TPX. The Tribolium (Tc), Drosophila (Dm), Anopheles (Ag) and Apis sequences are studied. As shown in the trees, duplication and divergence have given rise to gene clusters (shaded yellow for Tribolium and blue for Drosophila). Pink arrowheads denote nodes with high bootstrap values (>800 in 1,000 trials), whereas green lines connect the putative orthologs with 1:1, 1:1:1 or 1:1:1:1 relationships. (PPT 58 KB)
Additional data file 10: The sequences of four Tribolium (Tc), twelve Drosophila (Dm), five Anopheles (Ag), one Bombyx (Bm), one Manduca (Ms), and two Apis (Am) lysozymes are aligned and used to derive the tree (upper panel). Lineage-specific expansion (shaded in different colors) occurs quite extensively in this family of enzymes. For instance, four Tribolium lysozyme genes are found as a gene cluster (lower panel) at the same genomic location. Pink arrowheads at nodes indicate bootstrap values greater than 800 from 1,000 trials. A green bar links the putative orthologous pair. (PPT 48 KB)
Authors’ original submitted files for images
Below are the links to the authors’ original submitted files for images.
About this article
Cite this article
Zou, Z., Evans, J.D., Lu, Z. et al. Comparative genomic analysis of the Tribolium immune system. Genome Biol 8, R177 (2007) doi:10.1186/gb-2007-8-8-r177
- Additional Data File
- Holometabolous Insect
- Family Expansion
- Serpin Gene