VP-16-induced nucleotide pool changes and poly(ADP-ribose) synthesis: the role of VP-16 in interphase death

Exposure of human promyelocytic leukemia cell line (HL-60) to VP-16 resulted in accumulation of DNA strand breaks. Concomitantly, intracellular NAD levels fell at 1 h, followed by declines in ATP at 2 h and in GTP, CTP, and UTP at 3 h. Furthermore, marked morphological changes, such as loss of microvilli or bleb formation, appeared at 4 h and cell death by 8-10 h. The addition of an inhibitor of poly(ADP-ribose) polymerase, 3-aminobenzamide (5 mM), theophylline (2 mM), or thymidine (1 mM), prevented these sequential reductions of nucleotide pools and cell death. In fact, the activation of poly(ADP-ribose) synthesis was detectable within a few hours after treatment with VP-16, although it was smaller than that induced by N-methyl-N'-nitro-N-nitrosoguanidine. These results may suggest the possible role of activation of poly(ADP-ribosyl)ation in VP-16-induced nucleotide pool changes and subsequent interphase death.     

Flowering and Endogenous Levels of Plant Hormones in Lemna Species

The occurrence and endogenous level of various plant hormoneswere measured for the short-day plants Lemna paucicostata 151and 381 and the long-day plant Lemna gibba G3 to determine whetherany of them are involved in the photoperiodic control of flowering.ABA, IAA, GA₁, GA₂₉, GA₃₄, GA₅₃, trans- and cis-zeatin, trans-and cis-ribosyl zeatin, N⁶-(²-isopentenyl) adenine and N⁶-(²-isopentenyl)adenosine were definitely detected in each species, while GA₄was only detected in L. gibba G3 and GA₂₀ was only detectedin L. paucicostata 151. The endogenous levels of ABA and IAAwere in the range of 1–7 ng/g fr wt and were not significantlydifferent in vegetative and flowering plants. The endogenousgibberellin levels were generally higher in Lemna grown underlong-day rather than short-day conditions. The endogenous cytokininlevels were almost the same in both flowering and vegetativeplants of L. paucicostata 151 and 381. In L. gibba G3, however,the level of cis-ribosyl zeatin, N⁶-(²-isopentenyl) adenineand N⁶-(²-sopentenyl) adenosine were higher in vegetative thanin flowering plants. These results indicate that there is not necessarily a directrelation between endogenous plant hormone levels and flowering,and that the chemical basis for the photoperiodic control offlowering cannot be explained solely by changes in hormone levels.The possibility remains, however, that one or more of the planthormones has some influence of secondary importance on the floweringprocess in Lemna. (Received January 29, 1986; Accepted July 12, 1986)     

Synergistic effects of the myc and ras oncogenes on ganglioside synthesis by BALB/c 3T3 fibroblasts

The effects of oncogene activation on glycosphingolipid (GSL) synthesis by a mouse fibroblast clonal cell line were studied. A transfectant that expressed the activated ras gene showed a definite change in the composition of acidic GSLs, probably an increase in polysialoganglioside, while one that expressed the myc gene showed only a slight change. Neither transfectant grew in soft agar. However, another transfectant, which expressed both the myc and ras genes, and grew in soft agar, showed a more dramatic increase in the acidic GSL component. Thus, activations of the myc and ras oncogenes have a synergistic effect on GSL synthesis during transformation.     

Effects of Some Growth Regulators and Benzoic Acid Derivatives on Flower Initiation and Root Elongation of Pharbitis nil, Strain Kidachi

Seedlings of Pharbitis nil, strain Kidachi, were grown undercontinuous light at 20°C in vessels containing 5,000-mlnutrient solution, 24 plants per vessel. NAA (0.005–0.5µM), GA₃ (0.1–0.5 µM), kinetin (0.5–5µM), benzyladenine (0.05–5 µM) or abscisicacid (4 µM) added to the nutrient solution induced long-dayflowering, and the flowering was always accompanied by suppressionof root elongation. 3,4-Dichlorobenzoic acid (0.05–10µM) and some other benzoic acid derivatives which arehighly effective for the induction of flowering in Lemna paucicostataalso showed similar effects. Neither NAA, kinetin nor 3,4-dichlorobenzoicacid applied via the apical part of the hypocotyl could causeflowering or suppression of root elongation. Thus, the flower-inducingeffect of the above substances was presumed to be secondaryto the suppression of root elongation. Ethrel (1–50 µM)added to the nutrient solution suppressed root elongation, butdid not induce flowering probably because it has flower-inhibitingactivity. ¹ This paper is dedicated to the memory of Dr. Joji Ashida,the first president of the Japanese Society of Plant Physiologists. (Received December 15, 1982; Accepted February 25, 1983)     

Flowering behavior of the hybrids between strains 6746 and 371 of Lemna paucicostata hegelm

Lemna paucicostata Hegelm. 6746, a short-day plant, flowers even under continuous light when CuSo₄, AgNO₃, K₃[Fe(CN)₆], or benzoic acid are added to the medium, or when blue light is given exclusively. All other strains tested, including strain 371, did not flower under any of these conditions. Crossing between strains 371 (♀) and 6746 (♂) produced some seeds, although the reciprocal crossing did not. None of the hybrids flowered in response to AgNO₃, or blue light, and only a few flowered in response to CuSO₄. Most of the hybrids, on the other hand, flowered in response to K₃[Fe(CN)₆] or benzoic acid, although the responses were lower than the mean of the parental. Further analysis could not be made because self-pollination or crossing between the hybrids did not produce any seeds. However, since sensitivities to the above 5 factors were passed on to the F₁ hybrids in varying degrees, the extraordinary high sensitivities to these factors of strain 6746 are considered to be governed by different genes. Otherwise, a single (or a few) gene(s) governing the sensitivities to these factors would be differently expressed in the hybrids.     

Purification and characterization of membrane-bound inositolpolyphosphate 5-phosphatase

Membrane-bound inositolpolyphosphate 5-phosphatase was solubilized and highly purified from a microsomal fraction of rat liver. Its physiochemical and enzymological properties were compared with those of highly purified preparations of two types of soluble enzyme (soluble Type I and Type II) from rat brain. The molecular masses of the membrane-bound and soluble Type I enzymes were 32 kDa, while that of soluble Type II enzyme was 69 kDa, as determined by molecular sieve chromatography. The membrane-bound and soluble Type I enzymes showed similar broad peaks on isoelectric focusing (pI 5.8-6.4), while soluble Type II enzyme showed multiple peaks in the region between pI 4.0-5.8. All three enzymes required divalent cation for activity. Mg2+ was the most effective for both the membrane-bound and soluble Type I enzymes, while Co2+ enhanced soluble Type II enzyme activity about 1.5-fold relative to Mg2+ at 1 mM. The optimal pH of both the membrane-bound and soluble Type I enzymes was 7.8, while that of soluble Type II was 6.8. The Km values for inositol 1,4,5-trisphosphate [Ins(1,4,5)P3] of all three enzymes were similar (5-8 microM), but those for inositol 1,3,4,5-tetrakisphosphate [Ins(1,3,4,5)P4] were quite different, the Km values of membrane-bound and soluble Type I enzymes being 0.8 microM, while that of soluble Type II was 130 microM. These similarities between the membrane-bound and soluble Type I enzymes suggest that these two molecules may be the same protein, and that concentrations of Ins(1,4,5)P3 and Ins(1,3,4,5)P4, both of which are considered to play critical roles in the regulation of intracellular Ca2+-concentration, may be differently regulated by two functionally distinct enzymes.     

Non-systemic expression of a stress-responsive maize polyubiquitin gene (Ubi-1) in transgenic rice plants

We have used the promoter, 1st exon and 1st intron of the maize polyubiquitin gene (Ubi-1) for rice transformation experiments and revealed the characteristic expression of Ubi-1 gene: (1) Ubi-1 gene is not regulated systemically but rather individual cells respond independently to the heat or physical stress; (2) Ubi-1 gene changes its tissue-specific expression in response to stress treatment; (3) the expression of Ubi-1 gene is dependent on cell cycle.