Shinya Yamashita

JSAP1, a novel Jun N-terminal protein kinase (JNK)-binding protein that functions as a scaffold factor in the JNK signaling pathway

ABSTRACT The major components of the mitogen-activated protein kinase (MAPK) cascades are MAPK, MAPK kinase (MAPKK), and MAPKK kinase (MAPKKK). Recent rapid progress in identifying members of MAPK cascades suggests that a number of such signaling pathways exist in cells. To date, however, how the specificity and efficiency of the MAPK cascades is maintained is poorly understood. Here, we have identified a novel mouse protein, termed Jun N-terminal protein kinase (JNK)/stress-activated protein kinase-associated protein 1 (JSAP1), by a yeast two-hybrid screen, using JNK3 MAPK as the bait. Of the mammalian MAPKs tested (JNK1, JNK2, JNK3, ERK2, and p38α), JSAP1 preferentially coprecipitated with the JNKs in cotransfected COS-7 cells. JNK3 showed a higher binding affinity for JSAP1, compared with JNK1 and JNK2. In similar cotransfection studies, JSAP1 also interacted with SEK1 MAPKK and MEKK1 MAPKKK, which are involved in the JNK cascades. The regions of JSAP1 that bound JNK, SEK1, and MEKK1 were distinct from one another. JNK and MEKK1 also bound JSAP1 in vitro, suggesting that these interactions are direct. In contrast, only the activated form of SEK1 associated with JSAP1 in cotransfected COS-7 cells. The unstimulated SEK1 bound to MEKK1; thus, SEK1 might indirectly associate with JSAP1 through MEKK1. Although JSAP1 coprecipitated with MEK1 MAPKK and Raf-1 MAPKKK, and not MKK6 or MKK7 MAPKK, in cotransfected COS-7 cells, MEK1 and Raf-1 do not interfere with the binding of SEK1 and MEKK1 to JSAP1, respectively. Overexpression of full-length JSAP1 in COS-7 cells led to a considerable enhancement of JNK3 activation, and modest enhancement of JNK1 and JNK2 activation, by the MEKK1-SEK1 pathway. Deletion of the JNK- or MEKK1-binding regions resulted in a significant reduction in the enhancement of the JNK3 activation in COS-7 cells. These results suggest that JSAP1 functions as a scaffold protein in the JNK3 cascade. We also discuss a scaffolding role for JSAP1 in the JNK1 and JNK2 cascades.

Electroporation as a new technique for producing transgenic fish

A recombinant plasmid, pMV-GH, containing rainbow trout growth hormone cDNA fused to mouse metallothionein I promoter, was introduced into medaka (Oryzias latipes) by electroporation. Of 3109 fertilized eggs treated with electric pulses (750 V/cm, 50 microseconds, 5 times), 783 (25%) hatched out. Four percent of the hatchlings were transgenic. To obtain transgenic lines, 180 hatchlings were maintained and 35 of them grew into adult fish. Two of these fish were transgenic. When one transgenic fish was mated with a normal female, the transgene was found in all the F1 offspring assayed. In F2 offspring obtained by mating transgenic F1 fish, 88% were transgenic.

Two Distinct Isoforms of cDNA Encoding Rainbow Trout Androgen Receptors

Androgens play an important role in male sexual differentiation and development. The activity of androgens is mediated by an androgen receptor (AR), which binds to specific DNA recognition sites and regulates transcription. We describe here the isolation of two distinct rainbow trout cDNA clones, designated rtAR-α and rtAR-β, which contain the entire androgen receptor coding region. Comparison of the predicted amino acid sequence of rtAR-α to that of rtAR-β revealed 85% identity. Interestingly, despite this high homology, rtAR-α activated transcription of an androgen-responsive reporter gene in co-transfection assays, but rtAR-β did not. These results suggest that rainbow trout contains two distinct isoforms of androgen receptors whose functions differ. The region of rtAR-β responsible for its inactivity was mapped to its ligand binding domain by analyzing chimeras of the rtAR-α, rtAR-β, and rtGR-I (glucocorticoid) receptors. Alteration of any one of three out of four segments within this domain restored activity. Extracts made from COS-1 cells transfected with an rtAR-α expression plasmid produced a high level of [3H]mibolerone binding, whereas no binding was observed by extracts of cells transfected with an rtAR-β expression plasmid. These data demonstrate that the lack of transactivation activity of rtAR-β is due to its inability to bind hormone.

A gene that is related to SRY and is expressed in the testes encodes a leucine zipper-containing protein.

SRY-related cDNA encoding a protein with a high-mobility-group (HMG) box and a leucine zipper motif, which was designated SOX-LZ, was isolated from a rainbow trout testis cDNA library. Comparison of this cDNA with the mouse homologous cDNA isolated from a testis cDNA library exhibits an overall amino acid sequence identity of 77%, which is in striking contrast to the abrupt loss of amino acid sequence homology outside the HMG box found among mammalian SRY genes. In both rainbow trout and mice, Northern (RNA) blot analyses have revealed the presence of a testis-specific 3-kb-long SOX-LZ mRNA, and this transcript appeared coincidentally with the protamine mRNA, suggesting its expression in the germ line. A recombinant HMG box region protein encoded by SOX-LZ could bind strongly with an oligonucleotide containing an AACAAT sequence, which is also recognized by mouse Sry and Sox-5. Upon cotransfection into CHO cells, SOX-LZ transactivated transcription through its binding motif when the region including the leucine zipper motif was deleted [SOX-LZ (D105-356)]; however, the intact SOX-LZ failed to transactivate. The intact SOX-LZ could form homodimers through the leucine zipper, which resulted in inhibition of DNA binding by the HMG box, while SOX-LZ (D105-356), which was incapable of dimerization, showed specific binding with the AACAAT sequence. Thus, the repressed transactivation of the intact SOX-LZ in CHO cells was primarily attributable to the low level of DNA binding of SOX-LZ homodimers.

Fish glucocorticoid receptor with splicing variants in the DNA binding domain

Here we describe the isolation of a rainbow trout cDNA containing an entire GR coding region. Although the encoded protein is highly homologous to other GRs, especially in its DNA binding domain, it contains a nine amino acid insertion between the two zinc fingers. This novel form is found in all rainbow trout tissues examined; however, the testis also contains a splice variant lacking this insert, making it completely continuous to other GRs. In transient transfection assays of cultured cells, the two rainbow trout GR variants activated transcription from the glucocorticoid‐responsive mouse mammary tumor virus promoter to comparable levels.

Rainbow trout SOX9: cDNA cloning, gene structure and expression.

We have isolated and characterized rainbow trout SOX9 cDNA and genomic clones. The cDNA encodes a protein of 488 amino acids (aa) with an HMG box and has 70% aa sequence identity with human SOX9. The rainbow trout and human SOX9 genes show a similar gene structure, and the two introns in the coding region are located at conserved positions. In rainbow trout, the SOX9 mRNA was prominent in testis and brain.

Sequence and expression of a cDNA encoding the red seabream androgen receptor

The cDNA of the androgen receptor (AR) has been isolated from the ovary of red seabream, Pagrus major, and sequenced. The amino acid sequence of red seabream AR (rsAR) shows about 45% identity with those of Xenopus, rat, mouse, and human ARS. It is shown that rsAR has the ability to trans-activate the responsive gene depending on the presence of androgen.

A stable line of transgenic medaka (Oryzias latipes) carrying the CAT gene

Abstract A stable homozygous line of transgenic medaka (Oryzias latipes) was produced by injecting plasmid DNA containing rainbow trout metallothionein A promoter region followed by bacterial acetyltransferase gene (rtMT-A-CAT), into the cytoplasm of 111 fertilized eggs. The line transmitted active CAT gene to all of the offsprings until sixth generation in mendelian fashion. The Southern blot analysis and the crossing experiments indicated that the DNA was integrated into the chromosome. These results reveal that the medaka is a good model for basic studies of the production of transgenic fish.

cDNA cloning of a new member of the FTZ-F1 subfamily from a rainbow trout

We describe here cDNA cloning of an orphan nuclear receptor family member, tFZR1, which has a FTZ-F1 box. The amino acid sequences of the zinc finger domain and the FTZ-F1 box has 92.8% and 100% identity, respectively, with those of zebrafish FTZ-F1. On the other hand, the overall homology between tFZR1 and zebrafish FTZ-F1 is low (33.0%). The results indicate that tFZR1 is a new member of fushitarazu factor 1 (FTZ-F1) subfamily.

Expression of JNK cascade scaffold protein JSAP1 in the mouse nervous system.

The mitogen-activated protein kinase (MAPK) cascades consist of MAPK, MAPK kinase (MAPKK), and MAPKK kinase (MAPKKK). The specificity of activation of MAPK cascades may be determined, in part, by scaffold proteins that organize multi-enzyme complexes. We have earlier reported a scaffold protein JSAP1 (also known as JIP3) in the JNK MAPK cascade. We also showed that, of the adult mouse tissues tested, JSAP1 mRNA was predominantly expressed in brain. Here we report the localization of JSAP1 protein in mouse embryos and adult brain by immunohistochemical analysis. In embryos (E11-16), JSAP1 immunoreactivity was mainly found in the central and peripheral nervous systems, where it was localized to the cell bodies and/or axons of developing neurons, but not neural precursor cells. In the adult brain, immunoreactive JSAP1 was localized mostly to cell bodies in almost all neurons. We also showed that the expression of JSAP1 transcripts and proteins gradually increased during the neural differentiation of mouse P19 embryonal carcinoma (EC) cells. Furthermore, we showed that overexpressed JSAP1 facilitated the efficient activation of JNK by MEKK1 in P19 cells. These results suggest that JSAP1 may function as a scaffold protein for the JNK signaling module in neuronal cells.