Yohtaroh Takagaki

Genomic structure around joining segments and constant regions of swine T‐cell receptor α/δ (TRA/TRD) locus

A complete genomic region of 131·2 kb including the swine T‐cell receptor α/δ constant region (TRAC/TRDC) and joining segments (TRAJ/TRDJ) was sequenced. The structure of this region was strikingly conserved in comparison to that of human or mouse. All of the 61 TRAJ segments detected in the human genomic sequence were detected in the swine sequence and the sequence of the protein binding site of T early alpha, the sequence of the α enhancer element and the conserved sequence block between TRAJ3 and TRAJ4 are highly conserved. Insertion of the repetitive sequences that interspersed after the differentiation of the species in mammals such as short interspersed nucleotide elements is markedly suppressed in comparison to other genomic regions, while the composition of the mammalian‐wide interspersed sequences is relatively conserved in human and swine. This observation indicates the existence of a highly selective pressure to conserve this genomic region around TRAJ throughout the evolution of mammals.

Evidence for the expression of neonatal skeletal myosin heavy chain in primary myocardium and cardiac conduction tissue in the developing chick heart

We isolated a neonatal skeletal myosin heavy chain (MHC) cDNA clone, CV11E1, from a cDNA library of embryonic chick ventricle. At early cardiogenesis, diffuse expression of neonatal skeletal MHC mRNA was first detected in the heart tube at stage 10. During subsequent embryonic stages, the expression of the mRNA in the atrium was upregulated until shortly after birth. It then diminished, dramatically, and disappeared in the adult. On the other hand, in the ventricle, only a trace of the expression was detected throughout embryonic life and in the adult. However, transient expression of mRNA in the ventricle was observed, post‐hatching. At the protein level, during the embryonic stage, the atrial myocardium was stained diffusely with monoclonal antibody 2E9, specific for chick neonatal skeletal MHC, whereas the ventricles showed weak reactivity with 2E9. At the late embryonic and newly hatched stages, 2E9‐positive cells were located clearly in the subendocardial layer, and around the blood vessels of the atrial and ventricular myocardium. These results provide the first evidence that the neonatal skeletal MHC gene is expressed in developing chick hearts. This MHC appears during early cardiogenesis and is then localized in cardiac conduction cells. Dev Dyn 2000;217:37–49.

A mouse with a point mutation in plasma membrane Ca2+-ATPase isoform 2 gene showed the reduced Ca2+ influx in cerebellar neurons

We analyzed mutant mice showing behavioral defects such as severe tremor, up-and-down and side-to-side wriggling of neck without coordination, and found that the gene causing the defects was located between 46 and 60.55 centimorgans (cM) on the mouse chromosome 6. In this region, nucleotide transition of the plasma membrane Ca2+-ATPase isoform 2 (PMCA2) gene was found, which caused a glutamic acid to change into lysine. Since PMCA2 is expressed in the cerebellum and plays an important role to maintain the homeostasis of the intracellular Ca2+ as a Ca2+ pump, the behavioral defect can be ascribed to the impairment of Ca2+ regulation in neurons of the cerebellum. To confirm the defect of Ca2+ homeostasis in the mutant mice, we measured high K+-induced changes in intracellular Ca2+ concentration ([Ca2+]i) in the cerebellar neurons. Contrary to our expectation, the extent of the [Ca2+]i increase in all the regions tested in the cerebellar slice was far smaller than that of the wild type mice, while the resting [Ca2+]i remained almost unaltered. The rate of rise in [Ca2+]i during high K+-induced depolarization was significantly reduced, and the extrusion rate of increased [Ca2+]i was also reduced. These results suggested that voltage-gated Ca2+ channels were down-regulated in the mutant mice in order to regulate [Ca2+]i toward the normal homeostasis. The behavioral defects may be ascribed to the down-regulated Ca2+ homeostasis since dynamic changes in [Ca2+]i are important for various neuronal functions.

A Peptide Fragment of β Cardiac Myosin Heavy Chain (β-CMHC) Can Provoke Autoimmune Myocarditis as well as the Corresponding a Cardiac Myosin Heavy Chain (α-CMHC) Fragment

The validity of the general belief that a cardiac myosin heavy chain (α-CMHC) is primarily responsible for causing experimental autoimmune myocarditis because of the more profound tolerance induction to β-CMHC due to its expression during the embryonic stage has been examined. In order to completely avoid cross-contamination among components of the two myosin heavy chains, recombinant myosin fragments were synthesized in Escherichia coli using cDNA fragments of rat a- and (J-CMHC cloned by reverse transcription polymerase chain reaction (RT-PCR). Two fragments corresponding to amino acid residues 1107-1164 derived from a-and β-heavy chains were equally capable of provoking severe myocarditis in Lewis rats when immunized in complete Freunďs adjuvant. No significant differences in the severity, as judged from histological scoring, were observed between the diseases induced by the two different peptide fragments, indicating conclusively that β-CMHC is as pathogenic as α-CMHC.

TRAV gene usage in pig T-cell receptor alpha cDNA

Pig (Sus scrofa) TRA clones were isolated from cDNA libraries of total RNA from two different sources, the thymus of a 1-month-old LW strain pig and the peripheral blood lymphocytes of a 5-month-old Clawn strain pig. Among 103 complete TRA cDNA clones from both sources, 33 different TRAV genes were identified. By comparing their sequence identities against one another, these pig TRAV genes were grouped into 20 subgroups, including 13 subgroups, each containing only a single member. All of these pig subgroups gave corresponding human and mouse functional counterparts, suggesting their functional commonality. An exception was the Va01 gene segment, which lacked a functional human counterpart. The present report provides groundwork for studies on pig TRA expression.

Porcine Fas-ligand gene: genomic sequence analysis and comparison with human gene

Thymic Fas-ligand (FasL) cDNA and hepatic FasL genomic sequences were obtained from a 2-month-old LW pig. From these nucleotide sequences, amino acid sequence was deduced and compared with FasL sequences obtained from various animals. This comparison reveals that porcine FasL is closer to that of human, macaca and cat, and differs more from mouse and rat. The extracelluar domains of porcine and human FasL proteins appear to be functionally compatible. The complete genomic DNA sequence of porcine FasL was also compared with its human counterpart. Exons showed 80-89% nucleotide homology between pig and human, while introns showed 64-69% nucleotide homology. Sequence comparison by Harr plot analysis revealed many stretches within introns having identical sequences, suggesting that the sites may have unidentified common functions. One potential extra exon between exons 2 and 3 was located within porcine intron 2. This potential exon has no counterpart in human FasL intron 2. Whether or not this extra exon can be expressed and could cause additional immunological responses remains to be investigated. For future xenotransplantation, it is important to compare porcine and human genomic sequences, and to investigate their system compatibilities.

Primary structure of human hepatocellular carcinoma-associated aldehyde dehydrogenase

Tumor-associated aldehyde dehydrogenase (T-ALDH) is strongly expressed in hepatocellular carcinoma (HCC) but undetectable in normal liver. In the present study, this enzyme from human HCC, HCC T-ALDH, was purified and the partial amino acid sequences (384 residues) determined by direct protein sequencing matched the amino acid sequence (453 residues) deduced from cloned HCC T-ALDH cDNAs with an open reading frame. The coding sequences of HCC T-ALDH cDNA, human stomach ALDH3A1 cDNA [Hsu et al., J. Biol. Chem. 267 (1992) 3030-3037] and human squamous cell carcinoma (SCC) T-ALDH cDNA (Schuuring et al., GenBank I.D. M74542) matched one another except for discrepancies at four positions, with consequent P12R, I27F and S134A substitutions. R and A were found in HCC and SCC T-ALDHs, whereas P and S were present in stomach ALDH3A1. To confirm that these discrepancies would have general occurrence, coding sequences of HCC T-ALDH cDNAs from six patients and stomach ALDH3A1 cDNAs from two individuals were examined and all were found to encode ALDH3A1 having R, I and A at protein positions 12, 27 and 134, respectively, indicating HCC T-ALDH to be variant ALDH3A1 which is common in human stomach tissues.

Factors Involved in Signal Transduction During Vertebrate Myogenesis

Muscle is a contractile tissue of animals, dedicated to produce force and cause motion. In higher animals, there are two types of muscle tissue: (a) striated muscle, including all voluntary skeletal muscles and involuntary cardiac muscle, and (b) smooth muscle consisting of involuntary muscles, including those of the viscera, blood vessels, and uterus. Although muscle growth and regeneration take place throughout vertebrate life, the heart is the first organ to start functioning, with continued development until delivery. Skeletal muscles, on the other hand, develop in four successive, temporally distinct phases of embryonic, fetal, neonatal, and adult muscle with the postnatal phase being basically hypertrophy. Unlike terminally differentiated skeletal and cardiac muscles in adults, smooth muscle cells retain their plasticity and the phenotype can change reversibly in response to environmental changes. For the past 20 years, the availability of gene recombination technology directed the focus of studies on transcription factors and signaling molecules, and we would like to review what has been explored by recent studies on myogenesis.

Molecular Analysis of Long-Term Cultured Cardiac Stem Cells for Cardiac Regeneration

A c-Kit (CD117) is a well-known cell surface marker for adult somatic stem cells. We harvested c-Kit-positive cardiac stem cells (CSCs) from adult rat hearts by performing magnetic-activated cell sorting (MACS) and subjected them to long-term bulk culture more than 40 times. We made 11 attempts to obtain c-Kit-positive cells from adult (6–8-month-old) rats. Our initial expectation was of obtaining cells with homogenous cardiac phenotypes. However, each CSC bulk culture expressed varying degrees of the genes and cell surface markers belonging to cardiac and other mesenchymal lineages. The results suggested that these CSCs retained multiple developmental potential to some extent. Consequently, we investigated these CSCs in detail, hoping to establish the regeneration method by using c-Kit-positive cardiac cells [1–12].