DHCR24 gene knockout mice demonstrate lethal dermopathy with differentiation and maturation defects in the epidermis.

Desmosterolosis is an autosomal recessive disorder due to mutations in the 3beta-hydroxysterol-Delta24 reductase (DHCR24) gene that encodes an enzyme catalyzing the conversion of desmosterol to cholesterol. To date, only two patients have been reported with severe developmental defects including craniofacial abnormalities and limb malformations. We employed mice with targeted disruption of DHCR24 to understand the pathophysiology of desmosterolosis. All DHCR24-/- mice died within a few hours after birth. Their skin was wrinkleless and less pliant, leading to restricted movement and inability to suck (empty stomach). DHCR24 gene was expressed abundantly in the epidermis of control but not of DHCR24-/- mice. Accordingly, cholesterol was not detected whereas desmosterol was abundant in the epidermis of DHCR24-/- mice. Skin histology revealed thickened epidermis with few and smaller keratohyaline granules. Aberrant expression of keratins such as keratins 6 and 14 suggested hyperproliferative hyperkeratosis with undifferentiated keratinocytes throughout the epidermis. Altered expression of filaggrin, loricrin, and involcrin were also observed in the epidermis of DHCR24-/-. These findings suggested impaired skin barrier function. Indeed, increased trans-epidermal water loss and permeability of Lucifer yellow were observed in DHCR24-/- mice. DHCR24 thus plays crucial role for skin development and its proper function.

DHCR24-knockout embryonic fibroblasts are susceptible to serum withdrawal-induced apoptosis because of dysfunction of caveolae and insulin-Akt-Bad signaling.

The DHCR24 gene encodes an enzyme catalyzing the last step of cholesterol biosynthesis, the conversion of desmosterol to cholesterol. To elucidate the physiological significance of cholesterol biosynthesis in mammalian cells, we investigated proliferation of mouse embryonic fibroblasts (MEFs) prepared from DHCR24(-/-) mice. Both DHCR24(-/-) and wild-type MEFs proliferated in the presence of serum in culture media. However, the inhibition of external cholesterol supply by serum withdrawal induced apoptosis of DHCR24(-/-) MEFs, which was associated with a marked decrease in the intracellular and plasma membrane cholesterol levels, Akt inactivation, and Bad dephosphorylation. Insulin is an antiapoptotic factor capable of stimulating the Akt-Bad cascade, and its receptor (IR) is enriched in caveolae, cholesterol-rich microdomains of plasma membrane. We thus analyzed the association of IR and caveolae in the cholesterol-depleted MEFs. Subcellular fractionation and immunocytochemical analyses revealed that the IR and caveolin-1 contents were markedly reduced in the caveolae fraction of the MEFs, suggesting the disruption of caveolae, and that large amounts of IR were present apart from caveolin-1 on plasma membrane, indicating the uncoupling of IR with caveolae. Consistent with these findings, insulin-dependent phosphorylations of insulin receptor substrate-1, Akt, and Bad were impaired in the cholesterol-depleted MEFs. However, this impairment was partial because treatment of the MEFs with insulin restored Akt activation and prevented apoptosis. Cholesterol supply also prevented apoptosis. These results demonstrate that the cellular cholesterol biosynthesis is critical for the activation and maintenance of the Akt-Bad cell survival cascade in response to growth factors such as insulin.

Differential expression of cyclin-dependent kinase inhibitors, p27Kip1 and p57Kip2, by corticotropin in rat adrenal cortex.

An important role for the cyclin-dependent kinase inhibitors (CDKIs), p27Kip1 and p57Kip2, in the proliferation and differentiation of adrenal cells has been suggested by their knockout mice, which display adrenal hyperplasia. Adrenal development and function are primarily regulated by ACTH. In the present study, we investigated the effects of ACTH on the expression of p27Kip1, p57Kip2 and proliferating cell nuclear antigen (PCNA) in rat adrenals. Male Wistar rats were treated with dexamethasone (Dex) to inhibit endogenous ACTH secretion. ACTH was then administered to the rats, and the adrenals were examined by Western blot and immunohistochemical analyses. Dex treatment induced shrinkage of adrenals where no PCNA-expressing cells were detected, but most of the cells expressed p27Kip1. Subsequent ACTH treatment resulted in the marked suppression of p27Kip1 expression, specifically in adrenocortical cells at 12 h after the stimulus. At 48 h, the p27Kip1 suppression still continued in the cortex, while the PCNA-expressing cells appeared mainly around the zona glomerulosa and increased at 72 h. At this time, the p27Kip1-expressing cells also appeared in the same zone. In contrast to p27Kip1, the expression of p57Kip2 was not detected in the Dex-treated adrenal. However, its expression was markedly induced by ACTH in the zona glomerulosa at 48 and 72 h. The results demonstrate that the primary site for mitogenic action of ACTH in rat adrenocortex is the zona glomerulosa, and that ACTH modulates proliferation of adrenocortical cells by regulating p27Kip1 and p57Kip2 expression in a time- and site-specific manner.

Direct determination of the stereoisomeric composition of callosobruchusic acid, the copulation release pheromone of the azuki bean weevil, Callosobruchus chinensis L., by the 2D-Ohrui-Akasaka method.

The stereoisomeric composition of the copulation release pheromone of the azuki bean weevil, Callosobruchus chinensis L., was determined to be R:S=3.3-3.4:1 by the 2D-Ohrui-Akasaka method.

Molecular cloning of prostaglandin EP3 receptors from canine sensory ganglia and their facilitatory action on bradykinin-induced mobilization of intracellular calcium.

We previously demonstrated that the activation of prostaglandin E-prostanoid-3 (EP3) receptor sensitized the canine nociceptor response to bradykinin (BK). To elucidate the molecular mechanism for this sensitization, we cloned two cDNAs encoding EP3s with different C-terminals, from canine dorsal root ganglia, and established the transformed cell lines stably expressing them. In both transformants, EP3 agonist did not increase intracellular cAMP levels, but it attenuated forskolin-dependent cAMP accumulation in a pertussis toxin (PTX)-sensitive manner and increased intracellular calcium levels in a PTX-resistant manner, indicating that both EP3s can couple with Gi and Gq, but not with Gs proteins. As the nociceptor response to BK is mediated by BK B2 receptor, it was transfected into the transformants and the effects of EP3 agonist on BK-dependent calcium mobilization were investigated. When BK was applied twice with a 6-min interval, the second response was markedly attenuated. Pre-treatment with EP3 agonist had no effect on the initial response, but restored the second response in a PTX-sensitive manner. A protein kinase A inhibitor mimicked the effect of EP3 agonist. These results demonstrate that the activation of EP3 restores the response to BK by attenuating the desensitization of BK B2 receptor activity via Gi protein.

Glutathionylation of two cysteine residues in paired domain regulates DNA binding activity of Pax-8.

We reported that the first two cysteine residues out of three present in paired domain (PD), a DNA-binding domain, are responsible for redox regulation of Pax-8 DNA binding activity. We show that glutathionylation of these cysteines has a regulatory role in PD binding. Wild-type PD and its mutants with substitution of cysteine to serine were synthesized and named CCC, CSS, SCS, SSC, and SSS according to the positions of substituted cysteines. They were incubated in a buffer containing various ratios of GSH/GSSG and subjected to gel shift assay. Binding of CCC, CSS, and SCS was impaired with decreasing GSH/GSSG ratio, whereas that of SSC and SSS was not affected. Because [3H]glutathione was incorporated into CCC, CSS, and SCS, but not into SSC and SSS, the binding impairment was ascribed to glutathionylation of the redox-reactive cysteines. This oxidative inactivation of PD binding was reversed by a reductant dithiothreitol and by redox factor (Ref)-1 in vitro. To explore the glutathionylation in cells, Chinese hamster ovary cells overexpressing CSS and SCS were labeled with [35S]cysteine in the presence of cycloheximide. Immunoprecipitation with an antibody against PD revealed that treatment of the cells with an oxidant diamide induced the 35S incorporation into both mutants, suggesting the PD glutathionylation in cells. Since the two cysteine residues in PD are conserved in all Pax members, this novel posttranslational modification of PD would provide a new insight into molecular basis for modulation of Pax function.

Oxidoreductive modification of two cysteine residues in paired domain by Ref-1 regulates DNA-binding activity of Pax-8.

We have reported reversible oxidoreductive regulation of DNA-binding activity of Pax-8: oxidation inhibits its binding and subsequent reduction restores the binding. Here, we show that Cys-45 and Cys-57 in the paired domain of rat Pax-8, which are conserved in all Pax members, are responsible for the redox regulation of its binding. Electrophoretic mobility shift assay using deletion mutants and mutants with substitution of cysteine with serine revealed that oxidation by diamide of either Cys-45 or Cys-57 loses the DNA binding of Pax-8. An intracellular oxidoreductive enzyme redox factor-1 (Ref-1) could reduce the oxidized Cys-45 or Cys-57 and restored the binding. Furthermore, reporter gene assay showed that transcriptional activity of wild-type Pax-8 was enhanced by co-expression of Ref-1. When the mutant with double substitutions of Cys-45 and Cys-57, which was insensitive to oxidation, was transfected, the basal transactivation level was much higher than that of wild-type Pax-8, while it was not enhanced by Ref-1. These results demonstrated that oxidoreductive modification of Cys-45 and Cys-57 via Ref-1 plays a role in redox regulation of Pax-8 in living cells.

Novel human ZAKI-4 isoforms: hormonal and tissue-specific regulation and function as calcineurin inhibitors.

We identified a thyroid hormone [3,5,3'-tri-iodothyronine (T(3))]-responsive gene, ZAKI-4, in cultured human skin fibroblasts. It belongs to a family of genes that encode proteins containing a conserved motif. The motif binds to calcineurin and inhibits its phosphatase activity. In the present study, we have demonstrated three different ZAKI-4 transcripts, alpha, beta1 and beta2, in human brain by 5'- and 3'-RACE (rapid amplification of cDNA ends). The alpha transcript was identical with the one that we originally cloned from human fibroblasts and the other two are novel. The three transcripts are generated by alternative initiation and splicing from a single gene on the short arm of chromosome 6. It is predicted that beta1 and beta2 encode an identical protein product, beta, which differs from alpha in its N-terminus. Since alpha and beta contain an identical C-terminal region harbouring the conserved motif, both isoforms are suggested to inhibit calcineurin activity. Indeed, each isoform associates with calcineurin A and inhibits its activity in a similar manner, suggesting that the difference in N-terminus of each isoform does not affect the inhibitory function on calcineurin. An examination of the expression profile of the three transcripts in 12 human tissues revealed that the alpha transcript is expressed exclusively in the brain, whereas beta transcripts are expressed ubiquitously, most abundantly in brain, heart, skeletal muscle and kidney. It was also demonstrated that human skin fibroblasts express both alpha and beta transcripts, raising the question of which transcript is up-regulated by T(3). It was revealed that T(3) markedly induced the expression of alpha isoform but not of beta. This T(3)-mediated increase in the alpha isoform was associated with a significant decrease in endogenous calcineurin activity. These results suggest that the expression of ZAKI-4 isoforms is subjected to distinct hormonal as well as tissue-specific regulation, constituting a complex signalling network through inhibition of calcineurin.