Platypus TCRμ provides insight into the origins and evolution of a uniquely mammalian TCR locus

TCRμ is an unconventional TCR that was first discovered in marsupials and appears to be absent from placental mammals and nonmammals. In this study, we show that TCRμ is also present in the duckbill platypus, an egg-laying monotreme, consistent with TCRμ being ancient and present in the last common ancestor of all extant mammals. As in marsupials, platypus TCRμ is expressed in a form containing double V domains. These V domains more closely resemble Ab V than that of conventional TCR. Platypus TCRμ differs from its marsupial homolog by requiring two rounds of somatic DNA recombination to assemble both V exons and has a genomic organization resembling the likely ancestral form of the receptor genes. These results demonstrate that the ancestors of placental mammals would have had TCRμ but it has been lost from this lineage.     

Evolution of the variable gene segments and recombination signal sequences of the human T-cell receptor α/δ locus

The T-cell receptor (TCR) and loci are particularly interesting because of their unique genomic structure, in that the gene segments for each locus are interspersed. The origin of this remarkable gene segment arrangement is obscure. In this report, we investigated the evolution of the TCR and variable loci and their respective recombination signal sequences (RSSs). Our phylogenetic analyses divided the and variable gene segments into two major groups each with distinguishing motifs in both the framework and complementarity determining regions (CDRs). Sequence analyses revealed that TCR variable segments share similar CDR2 sequences with immunoglobulin light chain variable segments, possibly revealing similar evolutionary histories. Maximum likelihood analysis of the region on Chromosome 14q11.2 containing the loci revealed two possible ancestral TCR / variable segments, TRDV2 and TRAV1-1/1-2, respectively. Maximum parsimony revealed different evolutionary patterns between the variable segment and RSS of the same variable gene arguing for dissimilar evolutionary origins. Two models could account for this difference: a V(D)J recombination activity involving embedded heptamer-like motifs in the germline genome, or, more plausibly, an unequal sister chromatid crossing-over. Either mechanism would have resulted in increased diversity for the adaptive immune system.     

Systematic Comparative Evaluation of Methods for Investigating the TCRβ Repertoire

High-throughput sequencing has recently been applied to profile the high diversity of antibodyome/B cell receptors (BCRs) and T cell receptors (TCRs) among immune cells. To date, Multiplex PCR (MPCR) and 5’RACE are predominately used to enrich rearranged BCRs and TCRs. Both approaches have advantages and disadvantages; however, a systematic evaluation and direct comparison of them would benefit researchers in the selection of the most suitable method. In this study, we used both pooled control plasmids and spiked-in cells to benchmark the MPCR bias. RNA from three healthy donors was subsequently processed with the two methods to perform a comparative evaluation of the TCR β chain sequences. Both approaches demonstrated high reproducibility (R² = 0.9958 and 0.9878, respectively). No differences in gene usage were identified for most V/J genes (>60%), and an average of 52.03% of the CDR3 amino acid sequences overlapped. MPCR exhibited a certain degree of bias, in which the usage of several genes deviated from 5’RACE, and some V-J pairings were lost. In contrast, there was a smaller rate of effective data from 5’RACE (11.25% less compared with MPCR). Nevertheless, the methodological variability was smaller compared with the biological variability. Through direct comparison, these findings provide novel insights into the two experimental methods, which will prove to be valuable in immune repertoire research and its interpretation.     

Functional analysis of the chicken PPARγ gene 5'-flanking region and C/EBPα-mediated gene regulation

Peroxisome proliferator-activated receptor-γ (PPARγ) and CCAAT/enhancer binding protein-α (C/EBPα) are the master regulators of adipogenesis. The regulatory mechanism of PPARγ and C/EBPα gene expression is clear in mammals, however, little is known in chicken. The aim of the present study was to characterize chicken PPARγ promoter and investigate whether PPARγ could be regulated by C/EBPα in chickens. A 2-kb nucleotide sequence upstream of the start codon of chicken PPARγ gene was cloned and characterized by using bioinformatics and experimental approaches. This 2-kb promoter region exhibited strong promoter activity in DF1 cells. The reporter gene assay showed that the chicken C/EBPα could activate PPARγ gene promoter. Further study by electrophoretic mobility shift assay and mutational analysis revealed that the chicken C/EBPα could directly bind to and regulate the PPARγ gene promoter. Our results demonstrate that PPARγ can be directly regulated by C/EBPα in chickens.     

High-resolution analysis of cis-acting regulatory networks at the α-globin locus

We have combined the circular chromosome conformation capture protocol with high-throughput, genome-wide sequence analysis to characterize the cis-acting regulatory network at a single locus. In contrast to methods which identify large interacting regions (10–1000 kb), the 4C approach provides a comprehensive, high-resolution analysis of a specific locus with the aim of defining, in detail, the cis-regulatory elements controlling a single gene or gene cluster. Using the human α-globin locus as a model, we detected all known local and long-range interactions with this gene cluster. In addition, we identified two interactions with genes located 300 kb (NME4) and 625 kb (FAM173a) from the α-globin cluster.     

Comprehensive analysis and characterization of the TCR α chain sequences in the common marmoset

The common marmoset (Callithrix jacchus) is useful as a nonhuman primate model of human diseases. Although the marmoset model has great potential for studying autoimmune diseases and immune responses against pathogens, little information is available regarding the genes involved in adaptive immunity. Here, we identified one TCR α constant (TRAC), 46 TRAJ (joining), and 35 TRAV (variable) segments from marmoset cDNA. Marmoset TRAC, TRAJ, and TRAV shared 80%, 68–100%, and 79–98% identity with their human counterparts at the amino acid level, respectively. The amino acid sequences were less conserved in TRAC than in TCRβ chain constant (TRBC). Comparative analysis of TRAV between marmosets and humans showed that the rates of synonymous substitutions per site (d _S ) were not significantly different between the framework regions (FRs) and complementarity determining regions (CDRs), whereas the rates of nonsynonymous substitutions per site (d _N ) were significantly lower in the FRs than in CDRs. Interestingly, the d _N values of the CDRs were greater for TRBV than TRAV. These results suggested that after the divergence of Catarrhini from Platyrrhini, amino acid substitutions were decreased in the FRs by purifying selection and occurred more frequently in CDRβ than in CDRα by positive selection, probably depending on structural and functional constraints. This study provides not only useful information facilitating the investigation of adaptive immunity using the marmoset model but also new insight into the molecular evolution of the TCR heterodimer in primate species.     

Is physiology the locus of health/health promotion?

A current trend in physiology education involves the use of clinical vignettes to demonstrate the importance of knowing normal physiology to appreciate pathophysiology. Although laudable, in effect, such tactics promote the so-called "disease" model of medicine while at the same time suggesting that the only utility for the knowledge of physiology is to understand pathophysiology. This would seem to be at odds with health professions and institutions, who maintain their goal is to promote health. Yet, a search for the locus of "health" education in typical curricula is not easily found. Given the developing interest in biological systems as well as aging, it is suggested that these topics may provide a basis for locating physiology as the locus for understanding "health."     

Identification and characterization of TCRγ and TCRδ chains in channel catfish,Ictalurus punctatus

Channel catfish, Ictalurus punctatus, T cell receptors (TCR) γ and δ were identified by mining of expressed sequence tag databases, and full-length sequences were obtained by 5′-RACE and RT-PCR protocols. cDNAs for each of these TCR chains encode typical variable (V), diversity (D), joining (J), and constant (C) regions. Three TCRγ V families, seven TCRγ J sequences, and three TCRγ C sequences were identified from sequencing of cDNA. Primer walking on bacterial artificial chromosomes (BACs) confirmed that the TRG locus contained seven TRGJ segments and indicated that the locus consists of (Vγ3-Jγ6-Cγ2)–(Vγ1_n-Jγ7-Cγ3)–(Vγ2-Jγ5-Jγ4-Jγ3-Jγ2-Jγ1-Cγ1). In comparison for TCRδ, two V families, four TCRδ D sequences, one TCRδ J sequence, and one TCRδ C sequence were identified by cDNA sequencing. Importantly, the finding that some catfish TCRδ cDNAs contain TCR Vα-D-Jδ rearrangements and some TCRα cDNAs contain Vδ-Jα rearrangements strongly implies that the catfish TRA and TRD loci are linked. Finally, primer walking on BACs and Southern blotting suggest that catfish have four TRDD gene segments and a single TRDJ and TRDC gene. As in most vertebrates, all three reading frames of each of the catfish TRDD segments can be used in functional rearrangements, and more than one TRDD segment can be used in a single rearrangement. As expected, catfish TCRδ CDR3 regions are longer and more diverse than TCRγ CDR3 regions, and as a group they utilize more nucleotide additions and contain more nucleotide deletions than catfish TCRγ rearrangements.     

The impact of a large and frequent deletion in the human TCR β locus on antiviral immunity

The TCR plays a critical role in recognizing intracellular pathogens and initiating pathways leading to the destruction of infected cells by the immune system. Although genetic variability is known to greatly impact on the human immune system and the outcome of infection, the influence of sequence variation leading to the inactivation or deletion of TCR gene segments is unknown. To investigate this issue, we examined the CD8(+) T cell response to an HLA-B7-restricted epitope ((265)RPHERNGFTVL(275)) from the pp65 Ag of human CMV that was highly biased and frequently dominated by a public TCR β-chain encoded by the variable gene segment TRBV4-3. Approximately 40% of humans lack T cells expressing TRBV4-3 because of a 21.5-kb insertion/deletion polymorphism, but these individuals remain responsive to this epitope, using a diverse T cell repertoire characterized by private TCR usage. Although most residues within the bulged 11-mer peptide were accessible for TCR contact, the public and private TCRs showed distinct patterns of sensitivity to amino acid substitution at different positions within the peptide, thereby suggesting that the repertoire diversity generated in the absence of the dominant public TRBV4-3(+) TCR could lead to better protection from viral escape mutation. Thus, variation in the size of the TRBV repertoire clearly contributes toward interindividual variability in immune responses and is presumably maintained in many ethnic groups to enhance the diversity of Ag-specific T cell responses.     

Aδ afferent fiber stimulation activates descending noradrenergic system from the locus coeruleus

We compared the noradrenaline (NA) level in the dorsal horn following electrical stimulation of Aδ afferent nerve fibers in the peripheral nervous system between rats with bilateral lesions of the locus coeruleus (LC) and non-operated control rats by using a microdialysis technique combined with high performance liquid chromatography. Prior to Aδ afferent fiber stimulation, the NA content in the dialysate did not differ between the LC-lesioned and the control rats. During Aδ afferent fiber stimulation, in the LC-lesioned rats, the NA level did not change significantly compared to that before Aδ afferent fiber stimulation, whereas the NA level increased significantly in the control rats. There was a significant difference in the NA levels during Aδ afferent fiber stimulation between the two groups of rats. The result suggests that descending noradrenergic neurons from the LC is involved in the increase of the NA level in the spinal cord dorsal horn produced by Aδ afferent fiber stimulation.     

Comparative and evolutionary analysis of the rhesus macaque extended MHC class II region

The sequence-based map of a part of the rhesus macaque major histocompatibility complex (MHC) extended class II region is presented. The sequenced region encompasses 67,401 bp and contains the SACM2L, RING1, FABGL and KE4 genes, as well as the HTATSF1-like and ZNF-like pseudogenes. Similar to human, but different from rat and mouse, no class I genes are found in the SACM2L- RING1 interval. The rhesus macaque extended MHC class II region shows a high degree of conservation of exonic as well as intronic and intergenic sequences compared with the respective human region. It is concluded that this particular genomic organization of the extended class II region-i.e., the absence of class I genes and the presence of the HTATSF1-like and ZNF-like pseudogenes-can be traced back to a common ancestor of humans and rhesus macaques about 23 million years ago.     

Developmental regulation of the chicken δ1-crystallin gene: analysis by transgenesis and gene dissection

We previously reviewed what we had learned about the regulation of the δ1-crystallin gene through experiments using gene transfer techniques [Kondoh et al. (1986) Cell Differ. 19, 151–160]. It was concluded then that regulatory genetic elements for the lens-specific expression are associated with the δ1-crystallin gene, and that these chicken elements properly function in mammalian cells. In the last couple of years, we have made significant progress in the understanding of lens-specific δ-crystallin expression. This is owing to success in transgenesis of mouse with the δ1-crystallin gene and in functional dissection of the gene which led us to the discovery of an intragenic enhancer as the major determinant for lens-specific expression. In this article, we summarize these recent advances.     

Biochemical genetics of α-amylase isozymes of the chicken pancreas

In the chicken population at large, three electrophoretically distinct pancreatic alpha-amylase isozymes were discovered. The isozymes were designated Pa 1, Pa 2, and Pa 3. The local population of chickens, however, possessed only isozymes Pa 2 and Pa 3 present as three phenotypes: Amy-2 B, consisting of isozyme Pa2; Amy2 BC, consisting of isozymes Pa 2 plus Pa 3; and Amy2 C, consisting of isozyme Pa 3. Pancreatic biopsy permitted the establishment of a breeding flock with defined amylase phenotypes. Matings of this flock established that amylases are inherited as codominant alleles at a single genetic locus. Further, there was no evidence of ontogenetic modification of the amylase isozymes. It was observed that amylase isozymes Pa 2 and Pa 3 each generated a family of at least three faster-migrating amylolytic proteins. These post-translationally modified amylases were designated Pa Xa, Pa Xb, and Pa Xc, where X represents the number of the progenitor amylase. Structural analyses of purified amylases demonstrated that all amylase isozymes are nonglycosidated, monomeric molecules of molecular weight 55,000. In addition, the data are consistent with the hypothesis that the faster-migrating amylases are produced by deamidation of asparagine and/or glutamine residues.