The branching of the inflorescence and vegetative shoot and taxonomy of the genusKummerowia (Leguminosae)

A study of the branching of the inflorescence and the vegetative shoot of the genusKummerowia, consisting ofK. stipulacea (Maxim.) Makino andK. striata (Thunb.) Schindler, has led to the following conclusions: (1) the inflorescences of both species are reduced compound cymes, (2) the branching system of the inflorescence ofKummerowia is not clearly different from that of the vegetative shoot and there are some transitional forms between both systems, and (3) the inflorescence ofKummerowia is different from the racemose inflorescences ofLespedeza andCampylotropis. Based on the differences found in the branching system of the inflorescence,Kummerowia is distinctly separated fromLespedeza andCampylotropis and is more correctly treated as a distinct genus from the latter two.     

Expression of a moderately anionic peroxidase is induced by aluminum treatment in tobacco cells: Possible involvement of peroxidase isozymes in aluminum ion stress

To clarify the mechanism of aluminum (Al) toxicity and Al tolerance, we isolated a new clone (pAL201) from a tobacco cDNA library. Northern blot hybridization analysis indicated that the expression of pAL201 is induced by Al treatment and phosphate (P₁) starvation. The complete cDNA sequence suggested that this clone encodes a moderately anionic peroxidase (EC 1.11.1.7). Analysis by isoelectric focussing indicated that a moderately anionic peroxidase (approximately pI 6.7) and two cationic peroxidases (pI 9.2 and 9.7) in the soluble fraction are activated by Al treatment and P₁ starvation, while two moderately anionic isozymes are repressed by these stresses. We suppose that Al ion stress can control the activity of some peroxidase isozymes, one of which is probably induced by enhanced gene expression of pAL201. There is a possibility that some of these isozymes have some functions in Al ion stress.     

Promotion of Zygote Formation by Protein Kinase Inhibitors during the Sexual Development of Dictyostelium mucoroides

To analyze the possible involvement of protein kinases in the sexual development (macrocyst formation) of the cellular slime mold Dictyostelium mucoroides-7 (Dm7), the effects of several protein kinase inhibitors were examined. K252a, a potent inhibitor of protein kinase activities, promoted the sexual cell fusion, through enhancement of gamete formation. In contrast, staurosporine (structurally and functionally similar to K252a) inhibited markedly the progress of development including cell aggregation, thus resulting in the failure of cells to form mature macrocysts. The effective period of K252a was 5–7 hr after starvation, during which Dm7 cells could acquire fusion competence, and the inhibitory effect of cAMP on zygote formation was nullified by the co-application of K252a. Although KT5720 (a specific inhibitor of cAMP-dependent protein kinase) and W7 (a calmodulin inhibitor) had no effects on zygote formation when applied separately, their combined application enhanced zygote formation like K252a did. Neither calphostin C (a specific inhibitor of Ca²⁺-dependent protein kinase) nor herbimycin A (a specific inhibitor of tyrosine kinase) exerted a stimulative influence upon macrocyst formation. These results strongly suggest that the two signal transduction pathways mediated by cAMP-dependent protein kinase (PKA) and calmodulin are closely related to zygote formation, their blockage being favorable to zygote formation.     

Inhibition of macrophage nitric oxide production by arachidonate-cascade inhibitors

We examined whether inhibitors of the arachidonic acid cascade inhibited nitric oxide (NO) production, as measured by nitrite concentration, either in macrophages or by their cytosolic fractions. Nitrite production by peritoneal macrophages from mice receiving OK-432 treatment was significantly inhibited by phospholipase A₂ inhibitors [dexamethasone and 4-bromophenacyl bromide (4-BPB)], lipoxygenase inhibitors [nordihydroguaiaretic acid (NDGA) and ketoconazole] and a glutathioneS-transferase (leukotrienes LTA₄-LTC₄) inhibitor (ethacrynic acid). However, caffeic acid and esculetin, inhibitors of 5- and 12-lipoxygenase respectively, were not inhibitory. On the other hand, indomethacin, a cyclooxygenase inhibitor, slightly inhibited whereas another inhibitor, ibuprofen, did not. Inhibition of the nitrite production by dexamethasone, 4-BPB, NDGA and ethacrynic acid was also demonstrated when the macrophages were restimulated ex vivo with OK-432 or with lipopolysaccharide. The inhibitory activity of dexamethasone, NDGA and ethacrynic acid was significantly reduced by ex vivo restimulation with OK-432, whereas that of 4-BPB was hardly affected. Furthermore, the inhibitory activity of dexamethasone, NDGA and ethacrynic acid was much higher when the macrophages were continuously exposed to the agents than when they were pulsed. Meanwhile, inhibition by 4-BPB was almost the same with either treatment. In addition, the inhibitory activity of these agents was not blocked withl-arginine, a substrate of NO synthases, or with arachidonate metabolites (LTB₄, LTC₄ and LTE₄). Ethacrynic acid and 4-BPB, but not dexamethasone and NDGA, also inhibited nitrite production by the cytosolic fractions from OK-432-restimulated peritoneal macrophages, and the inhibitory activity of 4-BPB was superior to that of ethacrynic acid. These agents, however, did not inhibit nitrite production from sodium nitroprusside, a spontaneous NO-releasing compound. These results indicate that dexamethasone, 4-BPB, NDGA and ethacrynic acid inhibited the production of NO by macrophages through at least two different mechanisms: one was inhibited by dexamethasone, NDGA and ethacrynic acid and the other by 4-BPB. Furthermore, 4-BPB and ethacrynic acid directly inhibited the activity of the NO synthase in macrophages, suggesting that the agents work by binding to the active site(s) of the enzyme.     

Suppressive Effect of Liposomes Containing DNA Coding for Diphtheria Toxin A-Chain on Cells Transformed with Bovine Leukemia Virus

A recombinant plasmid which contained a gene for diphtheria toxin A-chain (DT-A) under the control of the long terminal repeat (LTR) of bovine leukemia virus (BLV) (BLV-LTR) was constructed to test a novel application of liposomes as antiviral agents. The promoter activity of BLV-LTR was estimated by the chloramphenicol acetyltransferase (CAT) assay using a plasmid which contains the coding sequence of CAT under the control of BLV-LTR (pBLVCAT). When BLV-infected cells were transfected with pBLVCAT, CAT activity was detected. BLV-uninfected cell lines, however, showed no detectable CAT activity. The plasmid DNA entrapped in liposomes was added to BLV-infected cells in culture. Syncytium formation induced by BLV-infected cells was effectively suppressed by the liposomes containing the gene for DT-A under the control of BLV-LTR. Conversely, liposomes containing the gene for DT-A without a promoter showed no such effect. DT-A gene-containing liposomes with BLV-LTR did not affect formation of syncytium induced by bovine immunodeficiency virus. These observations indicate that BLV-infected cells were readily targeted on the level of gene expression. This strategy could be applied to the treatment of BLV-induced B-cell proliferation of cattle, and further to other viral/neoplastic diseases where specific gene expression is exerted.     

A Nitrate-Inducible Plasma Membrane Protein of a Marine Alga, Heterosigma akashiwo

The rate of nitrate uptake by Heterosigma akashiwo cells thathad been cultured in medium with nitrate or ammonium ions asthe source of nitrogen was measured using¹⁵NO_3– The ratioof ¹⁵N/¹⁴N increased dramatically in nitrate-grown cells. Inammonium-grown cells, the ratio of ¹⁵N/¹⁴N did not increasefor 3 h but then it began to increase. Even when nitrate reductaseactivity was inhibited by tungstate, nitrate-grown cells couldtake up nitrate. Plasma membranes from nitrate-grown and ammonium-grown cellswere purified by the silica-microbead method, and polypeptidesassociated with the membranes were analyzed by SDS-PAGE andimmunostaining. A major polypeptide with a molecular mass of26 kDa appeared 3 h after the transfer of ammonium-grown cellsto nitrate-containing medium, and it disappeared 2 d after thetransfer of nitrate-grown cells to ammonium-containing medium.The 26 kDa polypeptide also appeared when cell growth shiftedfrom the logarithmic phase to the stationary phase and the ammoniumcontent of the medium decreased, even when the cells were culturedin ammonium-containing medium. (Received April 10, 1992; Accepted July 30, 1992)     

Spontaneous and Ethyl Methanesulfonate-Induced Mutations Controlling Viability in DROSOPHILA MELANOGASTER. III. Heterozygous Effect of Polygenic Mutations

Spontaneous and EMS-induced mutations were accumulated for several generations on the second chromosome of Drosophila melanogaster by keeping this chromosome heterozygous under conditions of minimal natural selection. This article reports studies of heterozygous effects of these mutants.--Both lethal and mildly deleterious mutants have a deleterious heterozygous effect. There was no discernible difference between heterozygotes in which all the mutants were on one chromosome and those where the mutants were distributed over both homologs; thus the coupling-repulsion effect of MUKAI and YAMAZAKI (1964, 1968) is not confirmed. The spontaneous polygenic mutants have a dominance of 0.4 to 0.5, and the same value is found at very low EMS doses. However, the value at higher EMS doses is only about half as high. Since the low doses have a large fraction of spontaneous mutants, the dominance of EMS mutants is less, in the range 0.1 to 0.3, but still larger than for lethals.     

Ligandin: An adventure in Liverland

Summary Ligandin is an abundant soluble protein which has at 1/2 of 2–3 days, is induced by many drugs and chemicals, and is stabilized in the absence of thyroid hormone. The protein is strategically concentrated in cells associated with transport and detoxification of many endogenous ligands, such as bilirubin, and exogenous ligands, such as drugs and chemicals. The protein is a dimer in rat liver. Whether the dimer is a primary gene product or at least two genes are involved is not known. The protein has broad, low affinity catalytic activity as a GSH-S-transferase for many ligands having electrophilic groups and hydrophobic domains. It catalyzes formation of GSH conjugates, noncovalently binds some ligands prior to their biotransformation or excretion in bile, and covalently binds other ligands, such as activated carcinogens. Recent studies include the possible role of ligandin in chemical carcinogenesis, diagnosis of inflammatory and neoplastic disease of the liver and kidney, and participation in intracellular transport. Although some of the roles that have been outlined are speculative, any single function is important. The GSH-Stransferases are primitive enzymes and non specific binding proteins but it is precisely their simplistic design that allows such protean serviceability.Ligandin illustrates a group of hepatic disposal mechanisms which involve bulk transport of ligands. Although specific uptake and transport mechanisms have been described for several hormones which enter the hepatocyte in small quantities and regulate intermediary metabolism and, possibly, cell maturation, bulk transport of ligands into, through and out of the liver involves mechanisms which accomodate many metabolites, drugs and chemicals of diverse structure. The liver is bathed in sewage which contains what we ingest or are injected with and potentially toxic products of intestinal microorganisms. The chemical formulas of the many substances which are metabolized by the liver provide a horror show of potentially reactive and toxic metabolites, mutagens and carcinogens. Despite this alimentary Love Canal, we and our livers do remarkably well. These hepatic disposal mechanisms, as exemplified by ligandin, evolved in ancient times. They are present, albeit sluggishly, in insects and ancient elasmobranchs. Hepatic uptake and removal mechanisms of high capacity, modest affinity and broad substrate range permit us to live in what has probably always been a threatening world.Abbreviations DAB N,N-dimethyl-4-amino azobenzene - GSH reduced glutathione - BSP bromosulfophthalein - SDS sodium dodecyl sulfate     

cDNA cloning of an extracellular dermal glycoprotein of carrot and its expression in response to wounding

Suspension-cultured cells of carrot (Daucus carota L.) synthesize and secrete a glycoprotein that is normally found only in dermal tissues (epidermis, endodermis and periderm). This protein, previously called GP57, is now referred to as EDGP (E xtracellular D ermal G lyco P rotein). We purified sufficient quantities of EDGP to obtain amino-acid sequences on two internal tryptic peptides and screened a cDNA library of young carrot roots with antiserum to EDGP and with oligonucleotides corresponding to the peptides. Here we report the derived amino-acid sequence of EDGP. Sequence comparisons show that it has 40% amino-acid sequence identity with 7S basic globulin, a protein that is released when soybean seeds are soaked in hot water for a few hours. We suggest that these two proteins belong to a new family of dermal proteins. As far as we know, this is the first reported derived amino-acid sequence for protein that is specific to the epidermis and other dermal tissues. The level of EDGP mRNA is low in dry seeds, but increases rapidly in growing seedlings as they develop dermal tissues. The level of mRNA is low in storage roots, but increases rapidly in response to wounding. The presence of EDGP in dermal tissues and its up-regulation in response to wounding indicate a role in the response of plants to biotic and-or abiotic stresses. An unusual feature of the amino-acid sequence of EDGP is that it contains a short motif, which is present at the active site of aspartyl proteases such as pepsin and chymosin.Abbreviations cDNA copy DNA - 2,4-D 2,4-dichlorophen-oxyacetic acid - EDGP extracellular dermal glycoprotein - 7SBG 7S basic globulin Supported by a contract from the United States Department of Energy (Energy Biosciences) (to M.J.C.) and a Grant-in-Aid for Special Research on Priority Areas (01660002, Cellular and Molecular Basis for Reproductive Processes in Plants) from the Ministry of Education, Science and Culture, and by the Fund from Basic Research Core System of Science and Technology Agency, Japan (to S.S.).