Conserved Regulatory Mechanisms of Tyrosinase Genes in Mice and Humans

In vertebrates, melanin production is restricted to pigment cells. This cell type-specific melanogenesis is considered to involve cell type-specific expression of the tyrosinase gene. Recently, there have been several reports that sequences in the 5’ flanking region of the mouse tyrosinase gene are responsible for cell type-specific expression of the transgene in mice. As the first step in the study of the evolution of the regulatory mechanisms for tyrosinase gene function in vertebrates, we constructed a fused gene, hg-Tyrs-J which includes a 1.0-kb 5’ flanking sequence of the human tyrosinase gene fused with mouse tyrosinase cDNA. By introducing the fused gene into fertilized eggs of albino mice, we obtained two mice that exhibited pigmentation in the skin and eyes and established a transgenic line from one of them. Further analyses revealed that the transgene was expressed cell type-specifically in these transgenic mice. We conclude, therefore, that the 1.0 kb 5’ upstream region of the human tyrosinase gene contains conserved cis-elements essential for cell type-specific expression of the tyrosinase genes in mice and humans. Results of our study may provide a clue to elucidate the evolutionary process of regulatory mechanisms of the tyrosinase gene.     

Indoleacetate oxidase activity of horseradish and other plant peroxidase isozymes

Zymographic analyses were carried out on a commercial peroxidasepreparation of horseradish (Cochlearia armorada) and crude extractsfrom several plant materials, such as roots of turnip, radish,spinach, sweet potato and morning glory, regarding the dualcatalytic activities of peroxidase- IA oxidase isozymes. A standardreacting mixture for the oxidase stain contained IA, TCP andFast Blue BB salt as substrate, promoting agent and dye coupler,respectively. An unidentified intermediate (or intermediates)resulting from enzymatic IA degradation was demonstrated tobe coupled with the diazonium salt and to form an insolublecomplex. At least four cathodal and four anodal peroxidase bandswere located in the horseradish preparation, the former appearingas dark IA oxidase bands and the latter as very faint bands. In the extracts from plant materials, less than half of thetotal peroxidase bands appeared as heavy to faint IA oxidasebands, whereas the remaining ones did not appear in the samecondition as that for the horseradish IA oxidase stain. Furthermore,it was noted that the intensity of each of the peroxidase bandswas not always correlated with that of the corresponding oxidasebands. ¹Contribution No. 683 from the National Institute of Genetics,Misima.     

PCR Amplification of Tetrahymena rDNA Segments Starting with Individual Cells

To facilitate studies of rDNA molecular genetics in Tetrahymena thermophila , we attempted the detection of polymorphisms in the nontranscribed spacers (NTSs) using polymerase chain reaction (PCR), starting with minute amounts of DNA. The targeted polymorphic regions are 85% adenine-thymine (AT). We found conditions of efficient and specific in vitro amplification of targeted segments in the replication domain of the 5'NTS and in the subtelomeric segment of the 3'NTS. The identity of the amplified segments was confirmed by restriction enzyme digestion and DNA sequence analysis. Digestion of the template DNA at restriction sites upstream and downstream of the targeted region increased the efficiency of amplification, presumably because the targeted segments are in a palindromic molecule. Starting from total cell DNA corresponding to as little as 0.03 picogram (equivalent to the DNA content of 0.003 cells or about 30 rDNA molecules), we observed the amplified band after agarose gel electrophoresis and ethidium bromide staining. The yield indicated more than 10-billion-fold amplification. Amplification of the subtelomeric fragment yielded homogeneous product of minimum possible length even though the telomeric-specific primer can bind, at least initially, at a multiplicity of GGGGTT repeats. Amplified 5'NTS product also was detected in an ethidium-bromide-stained gel when PCR was started with a single cell.     

Phylogeny of Regulatory Regions of Vertebrate Tyrosinase Genes

Highly homologous DNA elements were found to be shared by the upstream regions of the mouse tyrosinase and tyrosinase related protein (TRP-1) genes. Several nuclear proteins were shown to bind to both of these upstream regions. Shared homologous DNA elements were also found in the 5’ flanking sequences of Japanese quail and snapping turtle tyrosinase genes. Shared homologous nucleotide sequences were found to be scattered like an archipelago in the 5’ upstream regions of mouse and human tyrosinase genes. Comparisons between Japanese quail and snapping turtle tyrosinase genes gave similar results. On the contrary, mammalian (mouse and human) and nonmammalian (quail and snapping turtle) tyrosinase genes did not show significant homology in their 5’ upstream regions. In contrast, coding sequences in the first exons of vertebrate tyrosinase genes and their deduced amino acid sequences were found to be highly conserved except for their putative leader sequence-coding regions.     

Juvenile Hormone titre and vitellogenin gene expression related to ovarian development in primary reproductives compared with nymphs and nymphoid reproductives of the termite Reticulitermes speratus

To elucidate the reproductive cycle of termite queens, incipient colonies of Reticulitemes speratus (Isoptera: Rhinotermitidae) are established under laboratory conditions, and the transition of colony development is observed at 0.5, 1.5, 2.5, 3.5, and 7.5 months (stages I–V, respectively) after colony foundation. Ovarian development, vitellogenin gene expression and Juvenile Hormone (JH) titres are examined in the queens and in nonphysogastric nymphoids collected from natural colonies. A reproductive cycle in queens is observed, in which the oviposition rate is relatively higher during stages I and II, and then decreases during stages III and IV. Vitellogenic oocytes are not observed in the ovaries during stages III and IV, and the expression level of the vitellogenin gene is low, suggesting that egg production in queens is repressed during these stages. However, vitellogenin gene expression and egg deposition in queens resumes during stage V. Juvenile Hormone levels rise during the transition from nymphs to stage I queens, and elevated JH titres are observed also during stages III and IV. The decrease in JH titre in queens at stage II precedes the decline in vitellogenesis at stages III and IV. Thus, JH titre and vitellogenesis are correlated in an offset pattern. However, nonphysogastric nymphoid reproductives do not have vitellogenic oocytes in their ovaries, and their JH titre is two‐fold higher than that of queens, suggesting that elevated JH titre precedes vitellogenesis, as in queens.