Identification of TSC-22 as a potential tumor suppressor that is upregulated by Flt3-D835V but not Flt3-ITD.

Transforming growth factor-beta (TGF-beta)-stimulated clone-22 (TSC-22) was originally isolated as a TGF-beta-inducible gene. In this study, we identified TSC-22 as a potential leukemia suppressor. Two types of FMS-like tyrosine kinase-3 (Flt3) mutations are frequently found in acute myeloid leukemia: Flt3-ITD harboring an internal tandem duplication in the juxtamembrane domain associated with poor prognosis and Flt3-TKD harboring a point mutation in the kinase domain. Comparison of gene expression profiles between Flt3-ITD- and Flt3-TKD-transduced Ba/F3 cells revealed that constitutive activation of Flt3 by Flt3-TKD, but not Flt3-ITD, upregulated the expression of TSC-22. Importantly, treatment with an Flt3 inhibitor PKC412 or an Flt3 small interfering RNA decreased the expression level of TSC-22 in Flt3-TKD-transduced cells. Forced expression of TSC-22 suppressed the growth and accelerated the differentiation of several leukemia cell lines into monocytes, in particular, in combination with differentiation-inducing reagents. On the other hand, a dominant-negative form of TSC-22 accelerated the growth of Flt3-TKD-transduced 32Dcl.3 cells. Collectively, these results suggest that TSC-22 is a possible target of leukemia therapy.

Inhibitory Smad transcription factors protect arterial endothelial cells from apoptosis induced by BMP4.

Arterial endothelial cells (EC) at the adult stage differ from capillary and venous EC in terms of resistance to stress; however, the molecular basis of this resistance is not clear. Here, we found that arterial EC are highly resistant to bone morphogenetic protein (BMP)4-dependent apoptosis, whereas capillary and venous EC are not. The expression of inhibitory Smads (I-Smads) in arterial EC was well correlated with the resistance to this apoptosis. After the knockdown of I-Smad expression by short interfering RNA, the resistant arterial EC became sensitive to BMP4. In contrast, the ectopic expression of I-Smads in BMP4-sensitive cells suppressed BMP4-induced apoptosis. Furthermore, intravenous administration of BMP4 into mice caused hemorrhage of capillary EC in brain and lung. These results strongly suggest that BMP4/I-Smads are a novel regulator for the stability of vascular EC.

Removal of inorganic and organic mercurials by immobilized bacteria having mer-ppk fusion plasmids.

Feasibility of biological mercury removal from wastewater was examined by using alginate-immobilized cells of Escherichia coli carrying mer-ppk fusion plasmid pMKB18. Immobilized cells engineered to express mercury-transport system, organomercurial lyase and polyphosphate efficiently removed organic and inorganic mercury from contaminated wastewater over a wide concentration range of mercurials, probably via intracellular accumulation mediated by ppk-specified polyphosphate. Bioaccumulation of mercury was selective compared to other metals such as Cd(2+), Pb(2+) and Cr(6+). The immobilized cells could be used repeatedly (at least three times) without large loss of mercury removal activity. From these results, it is concluded that the mer-ppk fusion plasmid and the immobilized cells are useful for simultaneous removal of organic and inorganic mercury from contaminated wastewater.

Evaluation of ppk-specified polyphosphate as a mercury remedial tool.

To evaluate the utility of polyphosphate kinase gene (ppk)-specified polyphosphate in mercury remediation, a fusion plasmid, pMK27, with ppk from Klebsiella aerogenes and mercury transport genes, merT and merP, from Pseudomonas K-62, was constructed. The transcription and translation of ppk, merT and merP were found to be mercury-inducible. The ppk-specified polyphosphate was identified in cells preinduced by Hg2+, but not in cells without mercury induction, suggesting that the synthesis of polyphosphate is regulated by merR. The hypersensitive phenotype to Hg2+, shown by bacteria with pMRD141, which contains merT and merP, was almost completely restored to its original levels when the ppk was introduced into the plasmid, suggesting that the Hg2+-toxicity was reduced by the polyphosphate, probably via chelation formation. Bacteria with pMK27 accumulated approximately 6-fold more mercury than the bacteria with cloning vector, pUC119. These results clearly demonstrate that the polyphosphate is capable of retaining mercury in the cells without taxing the cells. Based on the results obtained in the present study, the fusion plasmid pMK27 may serve as a strategy for mercury remediation.

Stimulation of Ras guanine nucleotide exchange activity of Ras-GRF1/CDC25(Mm) upon tyrosine phosphorylation by the Cdc42-regulated kinase ACK1.

Ras-GRF1 is a brain-specific guanine nucleotide exchange factor (GEF) for Ras, whose activity is regulated in response to Ca(2+) influx and G protein-coupled receptor signals. In addition, Ras-GRF1 acts as a GEF for Rac when tyrosine-phosphorylated following G protein-coupled receptor stimulation. However, the mechanisms underlying the regulation of Ras-GRF1 functions remain incompletely understood. We show here that activated ACK1, a nonreceptor tyrosine kinase that belongs to the focal adhesion kinase family, causes tyrosine phosphorylation of Ras-GRF1. On the other hand, kinase-deficient ACK1 exerted no effect. GEF activity of Ras-GRF1 toward Ha-Ras, as defined by in vitro GDP binding and release assays, was augmented after tyrosine phosphorylation by ACK1. In contrast, GEF activity toward Rac1 remained latent, implying that ACK1 does not represent a tyrosine kinase that acts downstream of G protein-coupled receptors. Consistent with enhanced Ras-GEF activity, accumulation of the GTP-bound form of Ras within the cell was shown through the use of Ras-binding domain pull-down assays. Furthermore, Ras-dependent activation of ERK2 by Ras-GRF1 was enhanced following co-expression of activated ACK1. These results implicate ACK1 as an upstream modulator of Ras-GRF1 and suggest a signaling cascade consisting of Cdc42, ACK1, Ras-GRF1, and Ras in neuronal cells.

Role of MerT and MerP from Pseudomonas K-62 plasmid pMR26 in the transport of phenylmercury.

To investigate the individual role of MerT and MerP encoded by Pseudomonas K-62 pMR26 in the transport of phenylmercury, a series of mutants with a specific point mutation in merT and/or genetic deletion in merP were constructed and transformed into Escherichia coli XL1-Blue. Transport of phenylmercury across the cytoplasmic membrane of E. coli mediated by MerT and MerP was inhibited by NaCN and by cold temperatures. Deletion of merP reduced, but did not completely abolish the C6H5Hg+-hyperuptake and -hypersensitive phenotypes suggesting that transport of phenylmercury into the cytoplasm of E. coli is still occurring. Mutations of the vicinal cysteine residues (Cys24 and Cys25) in the first transmembrane region of MerT to serine caused complete loss of Hg2+-hyperuptake and -hypersensitivity, whereas the mutations did not affect the C6H5Hg+-hyperuptake and -hypersensitive phenotypes. In addition, no additive effect on the C6H5Hg+-hyperuptake and -hypersensitive phenotypes was found, when mutations of the two cysteines in MerT to serine were further introduced in the merP-deleted mutants. These results clearly demonstrated that the vicinal cysteine residues of MerT are not involved in the transport of C6H5Hg+, but indeed are involved in the transport of Hg2+ as previously reported.

Induction of rac-guanine nucleotide exchange activity of Ras-GRF1/CDC25(Mm) following phosphorylation by the nonreceptor tyrosine kinase Src.

Ras-GRF1/CDC25(Mm) has been implicated as a Ras-guanine nucleotide exchange factor (GEF) expressed in brain. Ras-GEF activity of Ras-GRF1 is augmented in response to Ca(2+) influx and G protein betagamma subunit (Gbetagamma) stimulation. Ras-GRF1 also acts as a GEF toward Rac, but not Rho and Cdc42, when activated by Gbetagamma-mediated signals. Tyrosine phosphorylation of Ras-GRF1 is critical for the induction of Rac-GEF activity as evidenced by inhibition by tyrosine kinase inhibitors. Herein, we show that the nonreceptor tyrosine kinase Src phosphorylates Ras-GRF1, thereby inducing Rac-GEF activity. Ras-GRF1 transiently expressed with v-Src was tyrosine-phosphorylated and showed significant GEF activity toward Rac, but not Rho and Cdc42, which was comparable with that induced by Gbetagamma. In contrast, Ras-GEF activity remained unchanged. The recombinant c-Src protein phosphorylated affinity-purified glutathione S-transferase-tagged Ras-GRF1 in vitro and thereby elicited Rac-GEF activity. Taken together, tyrosine phosphorylation by Src is sufficient for the induction of Rac-GEF activity of Ras-GRF1, which may imply the involvement of Src downstream of Gbetagamma to regulate Ras-GRF1.

DNA sequence and expression of a defective mer operon from Pseudomonas K-62 plasmid pMR26.

pMRB01 cloned from Pseudomonas K-62 plasmid pMR26 conferred bacterial hypersensitivity to organomercurials. DNA sequence analysis of a 2.3-kb SacI-Aor51HI fragment encompassing the whole region required for expression of the hypersensitive phenotype, revealed three open reading frames. The DNA sequence of these frames had 82.5%, 99.2% and 97.0% homology with the pDU1358 merR, merB and merD, respectively. The pMRB01 mer operon differs from the already known mer operon by the absence of the merT, merP and merA genes in this plasmid. An inverted repeat-like sequence upstream from the predicted merR was observed suggesting that this defective mer operon could be part of a transposon-like structure. Induction experiments and maxicell analysis of the mer-polypeptide showed that the lyase enzyme encoded by pMRB01 merB gene is mercurial-inducible and regulated by the transacting product of the merR gene. These results suggest that the hypersensitivity to organomercurials resulted from the expression of lyase activity encoded by the defective mer operon in the absence of reductase activity. The lyase enzyme encoded by pMRB01 merB catalyzes the protonolysis of the C-Hg bond of both arylmercury and alkylmercury compounds.

G protein beta gamma subunit-dependent Rac-guanine nucleotide exchange activity of Ras-GRF1/CDC25(Mm).

Ras-GRF1 has been implicated as a Ras-specific guanine nucleotide exchange factor (GEF), which mediates calcium- and muscarinic receptor-triggered signals in the brain. Although a Dbl homology domain known as a motif conserved among GEFs that target Rho family GTP-binding proteins exists in Ras-GRF1, GEF activity toward Rho family proteins has not been observed. Here we show that Ras-GRF1 exhibits Rac1-specific GEF activity when recovered from cells overexpressing G protein beta gamma subunits (Gbeta gamma). Substitution of conserved amino acids within the Dbl homology domain abolished this activity. Activation of the Rac pathway in the cell was further evidenced by synergistic activation of the stress kinase JNK1 by Ras-GRF1 and Gbeta gamma, which is sensitive to inhibitory action of dominant-negative Rac1(17N). In addition, association of Ras-GRF1 with Rac1(17N) was demonstrated by coimmunoprecipitation. Evidence for the involvement of tyrosine kinase(s) in Gbeta gamma-mediated induction of Rac1-specific GEF activity was provided by the use of specific inhibitors. These results suggest a role of Ras-GRF1 for regulating Rac-dependent as well as Ras-dependent signaling pathways, particularly in the brain functions.

The merG gene product is involved in phenylmercury resistance in Pseudomonas strain K-62.

The physiological function of a new gene, hereby designated merG, located between merA and merB on the broad-spectrum mer operon of Pseudomonas strain K-62 plasmid pMR26 was investigated. The 654-bp merG gene encodes a protein with a canonical leader sequence at its N terminus. The processing of the signal peptide of this protein was dose-dependently inhibited by sodium azide, a potent inhibitor of protein export. These results suggest that the mature MerG protein (ca. 20 kDa) may be located in the periplasm. Deletion of the merG gene from the broad-spectrum mer operon of pMR26 had no effect on the inorganic mercury resistance phenotype, but rendered the bacterium more sensitive to phenylmercury than its isogenic wild-type strain. Escherichia coli cells bearing pMU29, which carries a deletion of the merG gene, took up significantly more phenylmercury than the bacteria with the intact plasmid pMRA17. When the merG gene in a compatible plasmid was transformed into the E. coli strain carrying pMU29, the high uptake of and high sensitivity to phenylmercury were almost completely restored to their original levels. These results demonstrate that the merG gene is involved in phenylmercury resistance, presumably by reducing in-cell permeability to phenylmercury.

Distribution of attenuated goose parvoviruses in Muscovy ducklings.

With a polymerase chain reaction (PCR) method, goose parvovirus (GPV) DNA was detected in Muscovy ducklings inoculated with attenuated GPV strains, IH and IHC. Strain IH that had been passed 20 times in Muscovy duck embryos could be detected in ducklings at 2- to 28-days after oral inoculation by PCR, however, a cell culture adapted strain IHC that had been passed 15 times in Muscovy duck embryos and then successively 50 times in Muscovy duck embryo fibroblasts could not be detected by 6 days postinoculation by the oral route, but via intramuscular inoculation the virus was detected from 6 dpi. With both strains Muscovy ducklings produced neutralizing antibodies against GPV, but GPV could be recovered from heart muscles even in birds that had high titer of neutralizing antibody. This means that GPV remains in birds for a long period under the presence of high titer of neutralizing antibody in the serum. Recovery of the virus was consistent with PCR results with one exception in which the bird had a neutralizing antibody titer of more than 100,000. After inoculation of these strains, no clinical signs were detected in ducklings. These results suggest that strains IH and IHC can be candidates for live attenuated vaccine for GPV infection.

Functional reconstruction of total lower lip defects with a radial forearm free flap combined with a depressor anguli oris muscle transfer.

Two total lower lip reconstructions were accomplished by combining a radial forearm free flap and a depressor anguli oris muscle transfer. The radial forearm flap was used to reconstruct the inner surface of the lower lip. The bipedicled musculofascial flap, which includes both depressor anguli oris muscles, the depressor labii inferioris muscles, and the mentalis muscles, was elevated onto the chin and sutured superiorly to the modioli to obtain innervated sphincter function. Good results were obtained both aesthetically and functionally. Electromyography revealed almost normal mobility of the depressor anguli oris muscles 6 months after the operation. No drooling was seen during mastication, and no air leakage was observed during puffing of the cheeks. This is an effective procedure for the reconstruction of the sphincter function of the lower lip.

Arterialized venous flaps from the thenar and hypothenar regions for repairing finger pulp tissue losses.

Pulp tissue loss of the fingers was repaired with arterialized venous flaps from the thenar or hypothenar regions in 13 patients. Thirteen of the 15 flaps transferred survived completely. The thenar and hypothenar skin is durable and of appropriate texture for replacement of finger pulp defects. An average flap size of 2 x 3 cm was adequate for repairing the tissue loss of the fingers. These are not sensory flaps. However, they exhibited useful sensory recovery within 6 months of the operation. This method is simple and results in minimal donor-site morbidity. The arterialized venous flap is thus a useful alternative for the repair of finger pulp tissue losses.

Nucleotide sequence and expression of the organomercurial-resistance determinants from a Pseudomonas K-62 plasmid pMR26.

pMRA17 cloned from Pseudomonas K-62 plasmid pMR26 specified the resistance to both organic and inorganic mercurials. DNA sequence of this broad-spectrum resistant mer operon was determined. The 5504-bp sequence includes six open reading frames (ORFs), five of which were identified as merR, merT, merP, merA and merB in order by analysis of deletion mutants and by comparison with the DNA and amino acid (aa) sequences of previously sequenced mer operons. The merB encoding organomercurial lyase showed a less identity than the other mer genes with those from other broad-spectrum resistance operons. The remaining ORF named merE, located between merA and merB, had no significant homology with the published mer genes and seemed to be a new gene which may involve in phenylmercury resistance. Induction experiments and maxicell analyses of the mer-polypeptides revealed that pMRA17 mer operon expressed mercurial-inducible phenotype and the merB and merE as well as the merA were under the control of MerR which could activate not only by mercuric ion but also by organomercurials.

Design, synthesis, and biological activity of anti-angiogenic hypoxic cell radiosensitizer haloacetylcarbamoyl-2-nitroimidazoles.

We designed, synthesized, and evaluated haloacetylcarbamoyl-2-nitroimidazoles, including chloro (KIN-1800, TX-1835, and TX-1836) and bromo derivatives (TX-1844, TX-1845, and TX-1846), as potential hypoxic cell radiosensitizers with antiangiogenic activities. To establish biological function owing to the haloacetylcarbamoyl group in the side-chain, we compared their in vitro radiosensitizing activities with those of their parent 2-nitroimidazoles without haloacetylcarbamoyl groups: misonidazole (MISO), TX-1831, and TX-1832, respectively. Both tert-butoxy substituted derivatives. TX-1835 and TX-1845, were more potent radiosensitizers than TX-1831. The p-tert-butylphenoxy-substituted derivatives, TX-1836 and TX-1846, and the methoxysubstituted derivatives, KIN-1800 and TX-1844, were stronger radiosensitizers than TX-1832 and MISO. We examined the anti-angiogenic activities of these 2-nitroimidazole derivatives containing haloacetylcarbamoyl group by the rat lung endothelial (RLE) cell proliferation assay and chick embryo chorioallantoic membrane (chick CAM) angiogenesis assay and showed that haloacetylcarbamoyl-2-nitroimidazoles were more potent angiogenic inhibitors than the corresponding desacetylcarbamoyl-2-nitroimidazoles. The in vivo chick CAM angiogenesis assay showed that the strong bromoacetylcarbamoyl-2-nitroimidazole radiosensitizers, such as TX-1845 and TX-1846, were the strongest angiogenic inhibitors among them. We concluded that the bromoacetylcarbamoyl-2-nitroimidazole radiosensitizers, such as TX-1845 and TX-1846, are promising as anti-angiogenic hypoxic cell radiosensitizers.

Cytotoxic effect of sodium nitroprusside on PC12 cells.

To investigate the biochemical mechanism responsible for NO-induced neurotoxicity, the effect of sodium nitroprusside(SNP), a NO-generating agent, on PC12 cells was studied. The cell density was dose-dependently inhibited by SNP. Neuronally differentiated PC12 cells showed a higher resistance to SNP than the undifferentiated cells. The inhibitory effect was enhanced by 8-Br-cGMP, and reduced by methylene blue. However, 8-Br-cGMP alone had no significant cytotoxicity. SNP also inhibited [3H]-thymidine incorporation into the cells in a dose-dependent manner. The dose response curves for reducing cell density and for inhibiting thymidine incorporation, were found to be virtually superimposable. These results suggested that cytotoxicity elicited by NO seemed to be due to inhibition of DNA synthesis in PC12 cells.

Phenylmercury transport mediated by merT-merP genes of Pseudomonas K-62 plasmid pMR26.

The merB-merA-deleted plasmid pMRD141 which contains the intact merT-merP genes of pMRA17 conferred bacterial hypersensitivity not only to Hg2+ but also to C6H5Hg+. The bacterium with pMRD141 took up significantly more C6H5Hg+ than its isogenic strain with the cloning vector Bluescript II. The hypersensitivity to C6H5Hg+ seems to be based on hyperaccumulation of toxic C6H5Hg+ in the absence of detoxifying enzymes encoded by merB and merA. Our results show that bacterial transport of C6H5Hg+ into the cytoplasm is regulated by merT-merP genes.

Lack of involvement of merT and merP in methylmercury transport in mercury resistant Pseudomonas K-62.

To clarify whether the merT and merP genes play a role in the transport of methylmercury, we constructed a deletion plasmid, pMRD141 which lacked the genes conferring the organomercurial lyase and the mercuric reductase from plasmid, pMRA17 containing the entire broad-spectrum mercury resistance determinants of the 26 kb-plasmid from Pseudomonas K-62. Plasmid, pMRD141 showed hypersensitivity to Hg2+ but still expressed a normal sensitivity to methylmercury. The mercury-induced hypersensitive cells carrying pMRD141 took up appreciably more 203Hg2+ than the induced resistant cells with pMRA17 and the sensitive cells with cloning vector, Bluescript II SK(+) but no difference in the uptake of CH3(203)Hg2+ among these three strains was found. These results suggested that the merT and merP are only involved in the Hg2+ transport but do not participate in the transport of methylmercury.

Triangular flap repair of the congenital earlobe cleft.

Repair of a congenital earlobe cleft was performed on 16 patients using a new surgical technique derived from the Tennison-Randall triangular flap operation for cheiloplasty. There were no complications. This method was applied because the deformities and desired outcomes in the congenital earlobe cleft are similar to those of the cleft lip. Many papers have described surgery for congenital and acquired clefts; the former differs from the latter in some respects. The techniques described for the repair of acquired clefts are not always appropriate for congenital clefts. In addition, some operations specifically designed for congenital clefts require more complicated techniques. Using our technique to correct lobule deformities with a triangular flap in proportion to the angle and extent of the cleft, a superior cosmetic result was obtained in the repair of longitudinal earlobe clefts.

Organomercurial resistance determinants in Pseudomonas K-62 are present on two plasmids.

Pseudomonas strain K-62 was found to contain six plasmids. A mutant derivative cured of the 26-kb plasmid showed a higher sensitivity to mercurials; however, the strain was still able to volatilize them. Loss of the 68-kb plasmid in addition to the 26-kb plasmid abolished the ability of mercury volatilization in this strain and led to a further decrease in the level of mercurial resistance. These results are the first to demonstrate that the organomercurial resistance of Pseudomonas strain K-62 is plasmid-based, and that both the 26- and 68-kb plasmids are required for full expression of the mercurial resistance. Probes specific for the mer genes merA, merB, and merR strongly hybridized with the 26-kb plasmid, but not with the 68-kb plasmid. Two fragments of the 26-kb plasmid that hybridized with the mer genes were cloned and expressed in Escherichia coli. One recombinant plasmid (pMRA17) inducibly encoded a typical broad-spectrum mercurial resistance, whereas the other recombinant plasmid (pMRB01) constitutively conferred hypersensitivity to phenylmercury in the absence of mercuric reductase activity. The results suggest that the two organomercurial lyases in the cells are transcribed from different operator-promoters.