Identification and characterization of newt rad (ras associated with diabetes), a gene specifically expressed in regenerating limb muscle.

Formation of the blastema is a key event for limb regeneration in urodele amphibians, and skeletal muscle has been thought to be a major origin of the multipotent blastemal mesenchyme. In the present study, we used differential display to identify the genes expressed differentially in the muscle at the amputation site. We have isolated a cDNA clone that was upregulated during limb regeneration of the Japanese newt, Cynops pyrrhogaster. Deduced amino acid sequence revealed that the cloned cDNA was a newt homolog of rad (ras associated with diabetes), a gene overexpressed in skeletal muscle of Type II diabetic patients. Expression of newt rad (nrad) was not observed in unamputated normal limb muscle, increased within 4 hr after amputation, and then decreased to the level of normal muscle between 11 and 21 days after amputation. In situ hybridization showed that the transcripts of nrad were localized around most of the nuclei of skeletal muscle near the amputation site, indicating the expression of nrad in the multinucleate myotubes. This expression gradually decreased along the distal to proximal axis. No signals were observed in apical epidermal cap or blastemal mesenchyme. However, reverse transcription-PCR analysis detected a very low level of nrad expression in blastema, suggesting the carry-over of nrad expression in blastema from muscle. Administration of retinoic acid, which has been shown to cause an enhanced dedifferentiation in the regenerating limbs, increased nrad expression in more proximally located limb muscle tissues and prolonged the expression period. Thus, it was strongly suggested that the nrad expression is correlated with the dedifferentiation of myotubes of regenerating limbs. We also analyzed the expression of nrad during development. Transcripts were observed in immature oocytes, seen faintly or not seen thereafter until stage 57 when its expression increased again. These results indicated that nrad may play a role(s) in the developmental process as well as limb regeneration.

Regulation of gene expression by herbal medicines--a new paradigm of gene therapy for multifocal abnormalities of genes.

Japanese herbal medicine has long been considered as only supplementary therapy to Western medicine. However, we discovered that an herbal mixture, Saiko-keishi-to-ka shakuyaku (SK, TJ-960), showed regulatory function of gene expression such as increased expression of seizure-related gene PTZ-17, proto-oncogene c-fos and heat shock protein HSP 72. These results provide a scientific basis for an important ancient concept and usage of herbal mixtures as a "therapy against diseases which will be suffered in the future". Our results also give an adequate provide break-throughs for therapy and even prevention of intractable epilepsy, Alzheimer's disease, developmental disorders during pregnancy and the postnatal period, and also probably for prevention of metastasis or relapse of various cancers.

Expression of helix-loop-helix type negative regulators of differentiation during limb regeneration in urodeles and anurans.

The urodele is capable of regenerating its limb by forming a blastema even in the adult. By contrast, the anuran, which is phylogenetically close to the urodele, loses this ability during metamorphosis and forms blastema-like tissues that develop only into a spike-like structure in the adult. In order to compare the molecular mechanism of the formation and maintenance of the blastema between the urodele and anuran, the genes encoding helix-loop-helix (HLH) type negative regulators of differentiation were characterized for both the Japanese newt, Cynops pyrrhogaster, and African clawed frog, Xenopus laevis. Cynops homologs of Id2, Id3, and HES1 and Xenopus Id2 were identified. To learn the roles of these genes in regeneration, their expression was examined. The expression of Id2 and Id3 was low in unamputated limbs, but was up-regulated in blastemas of both adult newt and Xenopus. Interestingly, transcripts of the two Id genes showed specific localizations in the blastema and the expression patterns were very similar in both species through the early to medium bud stage. Id2 was expressed predominantly in the blastemal epidermis, and Id3 was expressed equally in the blastemal epidermis and mesenchyme including cells in precartilage condensations. HES1 expression was up-regulated in the newt blastemal epidermis. It was thought that the up-regulation of these genes in the epidermis was related to the proliferation of the cells and that increased expression of these genes in the mesenchyme was related to the undifferentiated state of the blastemal cells. These results and considerations strongly suggested that the state of differentiation is similar in the early to medium bud blastema of both urodeles and anurans. The expression of Id3 remained high through to the digits stage in newts. In contrast, its expression in Xenopus decreased in spike-like regenerates, which correspond to palette-digits stage of newt regenerates. From these results, it was suggested that the blastema redifferentiates earlier in the frog than in the newt, and therefore the timing of redifferentiation of the cartilage is crucial for complete regeneration.

Molecular mechanism of regulation of pentylenetetrazol-induced calcium entry by 3'-untranslated region of a seizure-related cDNA, PTZ-17, in Xenopus oocytes.

To determine the molecular mechanism of regulation of pentylenetetrazol (PTZ)-induced calcium entry by the seizure-related gene, PTZ-17, the role of the 3'-untranslated region (3'UTR) and also interaction between 3'UTR and intracellular factors were investigated. PTZ-induced calcium inward current in Xenopus oocytes injected with PTZ-17 RNA varied in magnitude among strains of mice: RNA derived from the DBA/2 mouse, which has a high susceptibility to convulsions, showed the largest current and that from the BALB/c mouse with a low susceptibility to convulsions showed no PTZ response. The sequence of 3'UTR showed alterations among mouse strains: 3'UTR of BALB/c showed a sequence alteration from T to G and that of DBA/2 showed a GTG insertion compared with that of B6. The 3'UTR also regulated the translation of chloramphenicol acetyltransferase (CAT) RNA depending on its sequence. A particular region within the 3'UTR demonstrated interaction with 60- and 47-kDa proteins. Sequence alterations in this region corresponded to disappearance or increase in PTZ-induced calcium entry. These findings suggest that a particular region within 3'UTR of the seizure-related gene, PTZ-17, is involved in PTZ-induced calcium entry via interaction between mRNA and specific RNA-binding proteins.

Nervous diseases and Kampo (Japanese herbal) medicine: a new paradigm of therapy against intractable nervous diseases.

Doctors who learned exclusively western medicine probably understand a priori Kampo (Japanese herbal) medicine merely as a kind of folk medicine which is not so effective and only a supplementary therapy to western medicine. We have been performing experiments on the mechanism of epileptogenesis mainly at the cellular level for a long time. During the research process, we unexpectedly encountered Kampo (Japanese herbal) medicine, and also performed research on the mechanism of action of a herbal mixture prescription, saiko-keishi-to-ka-shakuyaku (SK, TJ-960). Recently we discovered that SK acts to induce the best functional state of neurons and consequently intractable nervous symptoms disappear. SK has protective effects against neuron damage, normalizing effects on developmental defects of El mouse neurons, complete preventive effects on stress-induced increased c-fos and HSP 72 expression, complete suppression effects on the Reilly syndrome, complete normalizing effects on expression of the seizure-related gene, PTZ-17, and also, surprisingly, complete suppression effects on amyloid beta protein-induced neuron death. Such wide ranging effects which are preferable to functional maintenance and development of neurons can not be obtained by pure chemical drugs. These findings suggest that we should effectively use such ancient herbal prescriptions which show excellent preventive effects against neuron damage, enforcing action on natural healing forces and even regulatory action against adverse expression of genes, at least to prevent intractable nervous diseases, such as epilepsy, Alzheimer's disease and developmental defects of neurons during pregnancy and after birth. We should also create a future medicine, the 'third medicine', which is situated in a higher dimension than that of contemporary oriental and western medicines. For this purpose, it is necessary to perform research on the mechanism of action of Kampo (Japanese herbal) medicine.

Molecular cloning and characterization of the ABC transporter expressed in Trachea (ATET) gene from Drosophila melanogaster.

A novel member of the ATP-binding cassette (ABC) transporter proteins has been cloned from Drosophila melanogaster. The gene is designated as ABC Transporter Expressed in Trachea (Atet), because the transcript was localized to the respiratory system by in situ hybridization analysis of whole-mount embryos using digoxigenin-labeled RNA probes. The hybridization signal was also observed in amnioserosa. Northern blot analysis identified a single 4.5 kb mRNA expressed in all developmental stages at a relatively constant level. The Atet gene mapped to 24E on the left arm of the second chromosome. The Atet protein shows extensive homology with the Drosophila white gene product, which is reported to form heterodimers with the brown or scarlet gene product to transport guanine or tryptophan into the pigment cells in the compound eye. By analogy, Atet is suggested to be involved in transporting a small molecule after dimerization with a partner protein.

Sexual orientation in Drosophila is altered by the satori mutation in the sex-determination gene fruitless that encodes a zinc finger protein with a BTB domain.

We have isolated a new Drosophila mutant, satori (sat), the males of which do not court or copulate with female flies. The sat mutation comaps with fruitless (fru) at 91B and does not rescue the bisexual phenotype of fru, indicating that sat is allelic to fru (fru(sat)). The fru(sat) adult males lack a male-specific muscle, the muscle of Lawrence, as do adult males with other fru alleles. Molecular cloning and analyses of the genomic and complementary DNAs indicated that transcription of the fru locus yields several different transcripts. The sequence of fru cDNA clones revealed a long open reading frame that potentially encodes a putative transcription regulator with a BTB domain and two zinc finger motifs. In the 5' noncoding region, three putative transformer binding sites were identified in the female transcript but not in male transcripts. The fru gene is expressed in a population of brain cells, including those in the antennal lobe, that have been suggested to be involved in determination of male sexual orientation. We suggest that fru functions downstream of tra in the sex-determination cascade in some neural cells and that inappropriate sexual development of these cells in the fru mutants results in altered sexual orientation of the fly.

Cloning of SEZ-12 encoding seizure-related and membrane-bound adhesion protein.

SEZ-12 is one of the seizure-related cDNAs which was isolated by differential hybridization from primary cultured neurons from the mouse cerebral cortex with or without pentylenetetrazol (PTZ). SEZ-12 expression is transiently down-regulated in the mouse brain by injection of PTZ. To characterize SEZ-12, isolation of full-length cDNA and nucleotide sequence analysis were performed. The deduced amino acid sequence of SEZ-12 revealed that it encodes membrane-bound C-type lectin and has a significant homology to that of human cDNA, DGCR2 and IDD, which were cloned from a balanced translocation breakpoint associated with the DiGeorge syndrome. The isolated cDNA was about 4 kb in length and the message was expressed ubiquitously in various organs with low-abundance. Previously, we also cloned a transmembrane protein which is probably involved in cell-cell interaction by the differential hybridization technique. These findings suggest that transmembrane signaling in neuronal cells may have an important role in PTZ-induced seizure.

Cloning and characterization of seizure-related gene, SEZ-6.

SEZ-6 is a brain-specific cDNA. Its expression is increased by convulsant drug and it encodes membrane protein with five copies of short consensus repeat (SCR; complement C3b/C4b binding site) and two repeated sequences which are partially similar to CUB domain (complement Clr/s-like repeat). In this study, we analyzed the gene product of SEZ-6 by antibody raised against SEZ-6 peptide. In vitro translation and immunoblot revealed that SEZ-6 protein is modified post-translationally and expressed in the cerebrum and the cerebellum. To analyze the SEZ-6 expression in detail, we searched for other types of SEZ-6 cDNA by the polymerase chain reaction. Two additional types of cDNAs were isolated and sequence analysis showed that one cDNA encodes membrane protein with a different C-terminal region and the other encodes secreted protein with two SCRs and one CUB-like domain.

Cloning and expression of SEZ-6, a brain-specific and seizure-related cDNA.

To clarify the molecular mechanism of neuronal bursting activity of seizures, we have constructed a cDNA library from mouse cerebrum cortex-derived cells treated with pentylentetrazole (PTZ), one of the convulsant drugs. Using a differential screening technique, several cDNA clones whose expressions change with PTZ-treatment were obtained. Among these clones, SEZ-6 was characterized by increased expression with PTZ. Detailed northern analysis showed that expression of SEZ-6 was limited to the brain and increased by the administration of PTZ not only in in vitro cultured cells but also in vivo. Analysis of SEZ-6 cDNA revealed multiple motifs, including typical signal sequence, threonine-rich domain, five copies of short consensus repeats (SCRs) or sushi domain (complement C3b/C4b binding site), two repeated sequences which were partially similar to the CUB domain or complement C1r/s-like repeat, one transmembrane domain and a short cytoplasmic segment in the C-terminal region. Although many proteins with multiple SCRs or CUB domains other than complement-related proteins have been found, this is the first report about a brain-specific cDNA which encodes membrane protein with both SCRs and CUB domain-like segments. Based on these findings, it is evident that SEZ-6 encodes a novel type of protein which may be related to seizure.

Spatial, temporal, and hormonal regulation of epidermal keratin expression during development of the frog, Xenopus laevis.

To study the mechanism of hormone-induced keratin expression in the epidermis during Xenopus metamorphosis, a monospecific antibody was raised against a unique carboxy-terminal peptide of the 63-kDa keratin. Immunohistological analysis demonstrated that the onset of 63-kDa keratin expression showed distinct regional and temporal differences. The expression started at stage 54 in the hindlimb epidermis, at stage 57 in the head, and over 1 month later at stage 63 in the tail. The amount of 63-kDa keratin was further regulated during epidermal stratification and differentiation. The 63-kDa keratin was expressed first in basal epidermal cells before stratification began. The outer layer of the larval epidermis (periderm) did not express the 63-kDa keratin. As the cells moved out of basal layer, they stained more intensely with the anti-keratin antibody indicating that 63-kDa keratin synthesis is up-regulated during differentiation. Similar results were obtained with cultures of purified epidermal cells grown in high calcium conditions. Since we have shown that thyroid hormone (T3) induces 63-kDa keratin gene expression and hydrocortisone (HC) modulates T3 action we examined the effects of T3 and HC at the single cell level with the anti-keratin antibody. Immunostaining demonstrated that T3 alone and T3 plus HC increased the number of 63-kDa keratin-positive cells as well as the amount of 63-kDa keratin per cell. Unexpectedly these hormones had the same effects on head and tail epidermal cells even though the latter cells degenerate during metamorphosis. The major difference between tail and head cells was that the percentage 63-kDa keratin-producing cells was much greater in the head than in the tail.

Hormonal regulation of adult type keratin gene expression in larval epidermal cells of the frog Xenopus laevis.

Triiodothyronin (T3) is known to induce amphibian metamorphosis but other hormones such as glucocorticoids accelerate T3 action. The increase in plasma concentration of both T3 and glucocorticoids during metamorphic climax is correlated with the transformation of the epidermis from larval type (uncornified) to adult type (cornified). Previously we have shown that T3 induced adult-type 63 Kd keratin gene expression and cornification of the larval epidermis. In this study, we have examined the effects of T3 and hydrocortisone (HC) on the conversion of larval to adult epidermal cells in vitro. When larval epidermal cells were treated with both T3 and HC, they had a synergistic effect on adult-type keratin synthesis (both 63 Kd and 49 Kd keratins) and epidermal cornification. The synergistic effect between T3 and HC required a pretreatment with T3 for 3 days. During this time, addition of HC to cultures containing T3 did not change the amount of 63 Kd keratin mRNA. Thus, HC did not reduce the lag time for epidermal cells to respond to T3. After 4 days of hormone treatment, T3 increased the amount of 63 Kd keratin mRNA 9-fold while T3 and HC induced it 18-fold. When cultures were pretreated with T3 for 3 days, a 1 day treatment with HC was sufficient to obtain the synergistic effect. Thus the induction of 63 Kd keratin gene expression by T3 required a much longer lag (3 days) than the lag required for the synergistic action of T3 and HC (less than 1 day).(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium regulation of epidermal cell differentiation in the frog Xenopus laevis.

Adult frogs have a stratified epidermis with a keratinized stratum corneum. Since the extracellular calcium concentration is known to regulate differentiation of mammalian epidermal cells in vitro, we studied the effects of calcium on the terminal differentiation of frog epidermal cells. Exposure of the epidermal cells to a high concentration of calcium (greater than 0.2 mM) induced cornification and the synthesis of a 51 Kd acidic keratin. These data are very similar to the results from mammalian epidermal cell cultures, suggesting that the mechanism of terminal differentiation is conserved throughout the evolution of terrestrial vertebrates.

Isolation, characterization, and in vitro culture of larval and adult epidermal cells of the frog Xenopus laevis.

Methods for the isolation and in vitro culture of larval and adult Xenopus laevis epidermal cells have been developed. Epidermal cells of stage 52-54 tadpoles and adult epidermal cells were enzymatically dissociated and purified (98%) by Percoll-density centrifugation and unit-gravity sedimentation. Both cell types attached on fibronectin-coated dishes and proliferated for 1 wk when the proper medium was used. There were four significant differences between larval and adult cells: a) Adult cells had a greater buoyant density than larval cells. b) Keratin synthesis patterns were markedly different. c) A combination of medium F12 and Eagle's minimum essential medium was optimal for growth of larval cells whereas MCDB151 medium was optimal for adult cells. d) Adult cells needed fetal bovine serum (greater than 5%) whereas larval cells grew without fetal bovine serum. In contrast to these differences, larval and adult cells had two similar properties: a) Insulin had a potent effect on the growth of both cells, and b) The optimal Ca++ concentration for cell growth was quite low for both cell types; 0.1 mM for larval cells and below 0.05 mM for adult cells. These results suggest that low Ca++ levels are essential for both cornifying (adult) and uncornifying (larval) amphibian keratinocytes. The culture techniques described herein for larval and adult epidermal cells provide a new in vitro model for analyzing development of the epidermis during amphibian metamorphosis.