The complete sequences of Takifugu Toll-like receptor (TLR) loci and gene predictions from many draft genomes enable comprehensive molecular phylogenetic analysis. Strong selective pressure for recognition of and response to pathogen-associated molecular patterns has maintained a largely unchanging TLR recognition in all vertebrates. There are six major families of vertebrate TLRs. This repertoire is distinct from that of invertebrates. TLRs within a family recognize a general class of pathogen-associated molecular patterns. Most vertebrates have exactly one gene ortholog for each TLR family. The family including TLR1 has more speciesspecific adaptations than other families. A major family including TLR11 is represented in humans only by a pseudogene. Coincidental evolution plays a minor role in TLR evolution. The sequencing phase of this study produced finished genomic sequences for the 12 Takifugu rubripes TLRs. In addition, we have produced >70 gene models, including sequences from the opossum, chicken, frog, dog, sea urchin, and sea squirt. coincidental evolution ͉ multigene family ͉ concerted evolution T he Toll-like receptor (TLR) multigene family encodes important recognition receptors of the innate immune system that have been conserved in both the invertebrate and vertebrate lineages (1, 2). TLRs recognize a variety of endogenous and exogenous ligands; many of the latter are conserved molecules essential for pathogen survival. TLR genes have been recognized in a number of vertebrate genomes, and many partial and full-length sequences are available. Recent additions include draft predictions from the Japanese pufferfish Takifugu rubripes (3), the zebrafish Danio rerio (4-6), and the chicken Gallus gallus (7), and partially or fully sequenced mRNAs, including one from the goldfish Carassius auratus (8), several from the Japanese flounder Paralichthys olivaceus (9), and several from the rainbow trout Oncorhynchus mykiss (10). These papers provide incremental molecular phylogenetic analyses, and several reviews are available (11-13). Additionally, the draft genomes of the frog Xenopus tropicalis, chicken G. gallus, and opossum Monodelphis domesticus are now available. We present a complete molecular phylogenetic analysis of the known vertebrate TLR genes in the context of the complete genomic sequences of the T. rubripes TLRs. MethodsSequencing and Assembly. A draft genome sequence of T. rubripes was obtained by pairwise shotgun sequencing (14) through the efforts of an international collaboration (15). Sequence finishing was performed in part as described (16), with additional details provided in Supporting Text, which is published as supporting information on the PNAS web site.Bioinformatics. TLRs were identified as genes coding for both an N-terminal leucine-rich repeat (LRR) domain and a C-terminal Toll-IL-resistance (TIR) domain. To form the basis of our study, vertebrate sequences from the nonredundant DDBJ͞EMBL͞ NCBI database (GenBank) were identified by similarity to known TLRs (Data Set 1, which is...
BackgroundA large multigene family of NOD-like receptor (NLR) molecules have been described in mammals and implicated in immunity and apoptosis. Little information, however, exists concerning this gene family in non-mammalian taxa. This current study, therefore, provides an in-depth investigation of this gene family in lower vertebrates including extensive phylogenetic comparison of zebrafish NLRs with orthologs in tetrapods, and analysis of their tissue-specific expression.ResultsThree distinct NLR subfamilies were identified by mining genome databases of various non-mammalian vertebrates; the first subfamily (NLR-A) resembles mammalian NODs, the second (NLR-B) resembles mammalian NALPs, while the third (NLR-C) appears to be unique to teleost fish. In zebrafish, NLR-A and NLR-B subfamilies contain five and six genes respectively. The third subfamily is large, containing several hundred NLR-C genes, many of which are predicted to encode a C-terminal B30.2 domain. This subfamily most likely evolved from a NOD3-like molecule. Gene predictions for zebrafish NLRs were verified using sequence derived from ESTs or direct sequencing of cDNA. Reverse-transcriptase (RT)-PCR analysis confirmed expression of representative genes from each subfamily in selected tissues.ConclusionOur findings confirm the presence of multiple NLR gene orthologs, which form a large multigene family in teleostei. Although the functional significance of the three major NLR subfamilies is unclear, we speculate that conservation and abundance of NLR molecules in all teleostei genomes, reflects an essential role in cellular control, apoptosis or immunity throughout bony fish.
The T cell coreceptor CD4 is a transmembrane glycoprotein belonging to the Ig superfamily and is essential for cell-mediated immunity. Two different genes were identified in rainbow trout that resemble mammalian CD4. One (trout CD4) encodes four extracellular Ig domains reminiscent of mammalian CD4, whereas the other (CD4REL) codes for two Ig domains. Structural motifs within the amino acid sequences suggest that the two Ig domains of CD4REL duplicated to generate the four-domain molecule of CD4 and the related gene, lymphocyte activation gene-3. Here we present evidence that both of these molecules in trout are homologous to mammalian CD4 and that teleosts encode an additional CD4 family member, lymphocyte activation gene-3, which is a marker for activated T cells. The syntenic relationships of similar genes in other teleost and non-fish genomes provide evidence for the likely evolution of CD4-related molecules in vertebrates, with CD4REL likely representing the primordial form in fish. Expression of both CD4 genes is highest in the thymus and spleen, and mRNA expression of these genes is limited to surface IgM− lymphocytes. consistent with a role for T cell functionality. Finally, the intracellular regions of both CD4 and CD4REL possess the canonical CXC motif involved in the interaction of CD4 with p56LCK, implying that similar mechanisms for CD4+ T cell activation are present in all vertebrates. Our results therefore raise new questions about T cell development and functionality in lower vertebrates that cannot be answered by current mammalian models and, thus, is of fundamental importance for understanding the evolution of cell-mediated immunity in gnathosomes.
Host specificity is a phenomenon exhibited by all viruses. For the fish rhabdovirus infectious hematopoietic necrosis virus (IHNV), differential specificity of virus strains from the U and M genogroups has been established both in the field and in experimental challenges. In rainbow trout (Oncorhynchus mykiss), M IHNV strains are consistently more prevalent and more virulent than U IHNV. The basis of the differential ability of these two IHNV genogroups to cause disease in rainbow trout was investigated in live infection challenges with representative U and M IHNV strains. When IHNV was delivered by intraperitoneal injection, the mortality caused by U IHNV increased, indicating that the low virulence of U IHNV is partly due to inefficiency in entering the trout host. Analyses of in vivo replication showed that U IHNV consistently had lower prevalence and lower viral load than M IHNV during the course of infection. In analyses of the host immune response, M IHNV-infected fish consistently had higher and longer expression of innate immunerelated genes such as Mx-1. This suggests that the higher virulence of M IHNV is not due to suppression of the immune response in rainbow trout. Taken together, the results support a kinetics hypothesis wherein faster replication enables M IHNV to rapidly achieve a threshold level of virus necessary to override the strong host innate immune response.
Antiviral immunity in fish is not well understood. In mammals, Toll-like receptor (TLR) 3 is involved in double-stranded RNA recognition and host immune response activation. Here, we report the first identification of a rainbow trout TLR3 ortholog (rtTLR3), its genomic structure, and mRNA regulation. Six exons and five introns were identified from bacterial artificial chromosome (BAC) and expressed sequence tag (EST) sequencing, and this genomic organization is similar to mammalian and fish TLR3 genes. The putative 913 amino acid protein has a Toll/interleukin (IL)-1R (TIR) domain, a transmembrane domain, and leucine-rich repeats. In healthy trout, rtTLR3 is highly expressed in the liver, pyloric ceca, intestine, spleen, and anterior and trunk kidney tissues. To investigate whether rtTLR3 is involved in antiviral immunity, transcriptional regulation in vivo was examined by quantitative real-time polymerase chain reaction (PCR) after poly inosinic:cytidylic (I:C) and infectious hematopoietic necrosis virus (IHNV) treatments. TLR3 mRNA expression peaked 1 day after poly (I:C) injection of live animals, while the peak of gene expression after live IHNV challenge was observed on day 3. In vitro stimulation of rainbow trout anterior kidney leukocytes with poly (I:C) also enhanced rtTLR3 expression. Up-regulation was specific to viral challenge as there was no significant up-regulation of rtTLR3 mRNA levels in the spleen and a modest down-regulation in the anterior kidney after bath challenge with a gram-negative bacterial trout pathogen, Yersinia ruckeri. The sequence conservation of trout TLR3 and mRNA regulation after poly (I:C) or RNA virus exposures strongly suggest a role for trout TLR3 in antiviral immunity.
Infectious hematopoietic necrosis virus (IHNV) is an acute pathogen of salmonid fishes in North America, Europe and Asia and is reportable to the World Organization for Animal Health (OIE). Phylogenetic analysis has identified 5 major virus genogroups of IHNV worldwide, designated U, M, L, E and J; multiple subtypes also exist within those genogroups. Here, we report the development and validation of a universal IHNV reverse-transcriptase real-time PCR (RT-rPCR) assay targeting the IHNV nucleocapsid (N) gene. Properties of diagnostic sensitivity (DSe) and specificity (DSp) were defined using laboratory-challenged steelhead trout Oncorhynchus mykiss, and the new assay was compared to the OIE-accepted conventional PCR test and virus isolation in cell culture. The IHNV N gene RT-rPCR had 100% DSp and DSe and a higher estimated diagnostic odds ratio (DOR) than virus culture or conventional PCR. The RT-rPCR assay was highly repeatable within a laboratory and highly reproducible between laboratories. Field testing of the assay was conducted on a random sample of juvenile steelhead collected from a hatchery raceway experiencing an IHN epizootic. The RT-rPCR detected a greater number of positive samples than cell culture and there was 40% agreement between the 2 tests. Overall, the RT-rPCR assay was highly sensitive, specific, repeatable and reproducible and is suitable for use in a diagnostic setting.
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