Enhancement of extractable ethylene at light/dark transition in primary leaves of paclobutrazol-treated Phaseolus vulgaris seedlings

Paclobutrazol [(2RS,3RS)-1-(4-chlorophenyl)-4,4-dimethyl-2-(1,2,4-triazol-1-yl)pentan-3-ol], a triazole growth retardant, increased the 1-aminocyclopropane-1-carboxylic acid (ACC) level and resulted in reduced ethylene production, estimated as ethylene release in a closed system or by vacuum-extraction, in the primary leaves of Phaseolus vulgaris L. cv. Juliska seedlings exposed to light. At the light/dark transition, a definite enhancement of the endogenous ethylene level was observed by vacuum-extraction of primary leaves of treated plants and the ethylene deficiency of retardant-treated leaves ceased. The concentration of ACC after the light/dark transition followed the pattern for ethylene, and the increase in ACC content was paralleled by a decrease in malonyl-ACC.
It is concluded that the internal level of ethylene is not necessarily lower in the primary leaves of paclobutrazol-treated bean plants, but under special environmental conditions in vivo it may reach that of the control.     

The structural features of effective antagonists of the luteinizing hormone releasing hormone

Summary The structure-activity data of 6 years on 395 analogs of the luteinizing hormone releasing hormone (LHRH) have been studied to determine effective substituents for the ten positions for maximal antiovulatory activity and minimal histamine release. The numbers of substituents studied in the ten positions are as follows: (41)¹-(12)²-(12)³-(5)⁴-(47)⁵-(52)⁶-(16)⁷-(18)⁸-(4)⁹-(8)¹⁰. In position 1, DNal and DQal were effective with the former being more frequently the better substituent. DpClPhe was uniquely effective in position 2. Positions 3 and 4 are very sensitive to change. D3Pal in position 3 and Ser in position 4 of LHRH were in the best antagonists. PicLys and cPzACAla were the most successful residues in position 5 with cPzACAla being the better substituent. Position 6 was the most flexible and many substituents were effective; particularly DPicLys. Leu⁷ was most often present in the best antagonists. In position 8, Arg was effective for both antiovulatory activity and histamine release; ILys was effective for potency and lesser histamine release. Pro⁹ of LHRH was retained. DAlaNH₂ ¹⁰ was in the best antagonists.Abbreviations AABLys N -(4-acetylaminobenzoyl)lysine - AALys N -anisinoyl-lysine - AAPhe 3-(4-acetylaminophenyl)lysine - Abu 2-aminobutyric acid - ACLys N -(6-aminocaproyl)lysine - ACyh 1-aminocyclohexanecarboxylic acid - ACyp 1-aminocyclopentanecarboxylic acid - Aile alloisoleucine - AnGlu 4-(4-methoxy-phenylcarbamoyl)-2-aminobutyric acid - 2ANic 2-aminonicotinic acid - 6ANic 6-aminonicotinic acid - APic 6-aminopicolinic acid - APh 4-aminobenzoic acid - APhe 4-aminophynylalanine - APz 3-amino-2-pyrazinecarboxylic acid - Aze azetidine-2-carboxylic acid - Bim 5-benzimidazolecarboxylic acid - BzLys N -benzoyllysine - Cit citrulline - Cl₂Phe 3-(3,4-dichlorphenyl)alanine - cPzACAla cis-3-(4-pyrazinylcarbonylaminocyclohexyl)alnine - cPmACAla cis-3-[4-(4-pyrimidylcarbonyl)aminocyclohexyl]alanine - Dbf 3-(2-dibenzofuranyl)alanine - DMGLys N -(N,N-dimethylglycyl)lysine - Dpo N -(4,6-dimethyl-2-pyrimidyl)-ornithine - F₂Ala 3,3-difluoroalanine - hNal 4-(2-naphthyl)-2-aminobutyric acid - HOBLys N -(4-hydroxybenzoyl)lysine - hpClPhe 4-(4-chlorophenyl)-2-amino-butyric acid - Hse homoserine, 2-amino-4-hydroxybutanoic acid - ICapLys N -(6-isopropylaminocaproyl)lysine - ILys N -isopropyllysine - Ind indoline-2-carboxylic acid - INicLys N -isonicotinoyllysine - IOrn N -isopropylornithine - Me₃Arg N^G,N^G,N^G-trimethylarginine - Me₂Lys N ,N -dimethyllysine - MNal 3-[(6-methyl)-2-naphtyl]alanine - MNicLys N -(6-methylpicolinoyl)lysine - MPicLys N -(6-methylpicolinoyl)lysine - MOB 4-methoxybenzoyl - MpClPhe N-methyl-3-(4-chlorphenyl)lysine - MPZGlu glutamic acid,-4-methylpiperazine - Nal 3-(2-naphthyl)alanine - Nap 2-naphthoic acid - NicLys N -nicotinoyllysine - NO₂B 4-nitrobenzoyl - NO₂Phe 3-(4-nitrophenyl)alanine - oClPhe 3-(2-chlorphenyl)alanine - Opt O-phenyl-tyrosine - Pal 3-(3-pyridyl)alanine - 2Pal 3-(2-pyridyl)alanine - 2PALys N -(3-pyridylacetyl)lysine - pCapLys N -(6-picolinoylaminocaproyl)lysine - pClPhe 3-(4-chlorophenyl)alanine - pFPhe 3-(4-fluorophenyl)-alanine - Pic picolinic acid - PicLys N -picolinoyllysine - Pip piperidine-2-car-boxylic acid - PmcLys N -(4-pyrimidylcarbonyl)lysine - Ptf 3-(4-trifluromethyl phenyl)alanine - Pz pyrazinecarboxylic acid - PzAla 3-pyrazinylalanine - PzAPhe 3-(4-pyrazinylcarbonylaminophenyl)alanine - Qal 3-(3-quinolyl)alanine - Qnd-Lys N -quinaldoyllysine - Qui 3-quinolinecarboxylic acid - Qux 2-quinoxalinecarboxylic acid - Tic 1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid - TinGly 2-thienylglycine - tNACAla trans-3-(4-nicotinoylaminocyclohexyl)-alanine - tPACAla trans-3-(4-picolinoylaminocyclohexyl)alanine     

Effect of arachidonic acid on [3H]d-aspartate outflow in the rat hippocampus

The aim of this study was to investigate the effect of arachidonic acid on [³H]d-aspartate outflow in rat hippocampus synaptosomes and slices. Arachidonic acid 1) increased basal outflow of [³H]d-aspartate in both synaptosomes and slices, and 2) increased K⁺-evoked overflow in slices but not in synaptosomes. The latter effect was dependent (at least in part) on arachidonic acid metabolism, most likely mediated by lipo-oxygenase metabolites and free radical production. It was prevented by nordihydroguaiaretic acid but not by indomethacin, and was significantly reduced by free radical scavengers (superoxide-desmutase and catalase). This effect was dependent upon stimulation since it could not be observed after a continuous perfusion of arachidonic acid in the absence of stimulation. Furthermore, it was long-lasting since a 30 min perfusion of arachidonic acid was sufficient to exert a significant effect on a stimulation following termination of the application.     

Taurine in the developing cat: Uptake and release in different brain areas

Taurine is an important modulator of neuronal activity in the immature brain. In kittens, taurine deficiency causes serious dysfunction in the cerebellar and cerebral visual cortex. The processes of taurine transport in vitro were now studied for the first time in different brain areas in developing and adult cats. The uptake of taurine consisted initially of two saturable components, high- and low-affinity, in synaptosomal preparations from the developing cerebral cortex and cerebellum, but the high-affinity uptake component completely disappeared during maturation. The release of both endogenous and preloaded labeled taurine from brain slices measured in a superfusion system was severalfold stimulated with a slow onset by depolarizing K⁺ (50 mM) concentrations. K⁺ stimulation released markedly more taurine from the cerebral cortex, cerebellum and brain stem in kittens than in adult cats. The responses were largest in the cerebellum. Both uptake and release of taurine are thus highly efficient in the brain of kittens and may be of significance in view of the vulnerability of cats to taurine deficiency.     

Effects of chelators on iron uptake and release by the brain in the rat

The iron chelators desferrioxamine (DFO), pyridoxal isonicotinoyl hydrazone (PIH), 2,2-bipyridine, diethylenetriamine penta-acetic acid (DTPA) and 1,2 dimethyl-3-hydroxy pyrid-4-one (CP20) were analysed for their ability to change⁵⁹Fe uptake and release from the brain of 15- and 63-day rats either during or after intravenous injection of⁵⁹Fe-¹²⁵I-transferrin. DTPA was the only chelator unable to significantly reduce iron uptake into the brain of 15-day rats. This indicates that iron is not released from transferrin at the luminal surface of brain capillary endothelial cells. CP20 was able to reduce iron uptake in the brain by 85% compared to 28% with DFO. Only CP20 was able to significantly reduce brain iron uptake in 63 day rats. Once⁵⁹Fe had entered the brain no chelator used was able to mediate its release. All of the chelators except CP20 had similar effects on femur iron uptake as they did on brain uptake, suggesting similar iron uptake mechanisms. It is concluded that during the passage of transferrin-bound iron into the brain the iron is released from transferrin within endothelial cells after endocytosis of transferrin.     

In vitro TRH release from hypothalamus slices varies during the diurnal cycle

We have previously described a daily rhythm in thyrotropin releasing hormone (TRH) and TRH mRNA in the rat hypothalamus. To determine whether TRH release fluctuates in a diurnal manner, we have measured basal and potassium stimulated release from hypothalamic slices, and compared it to release from olfactory bulb slices, during the diurnal cycle. Basal TRH release was higher at 7:00 h than at any other time (1:00, 13:00 or 19:00 h) in either hypothalamus or olfactory bulb. The ratio of stimulated over basal release was higher in the hypothalamus at 19:00 h, when TRH content was highest. Potassium stimulated TRH release from olfactory bulb was not different from basal release at any time. TRH release fluctuations were not due to a rhythm of extracellular inactivation: the activity of pyroglutamyl aminopeptidase II, an ectoenzyme responsible for TRH inactivation, was constant throughout the cycle. Our data demonstrate that diurnal variations of TRH release occur in vitro and that the enhanced responsiveness to potassium stimulation in hypothalamus is correlated with increased levels of peptide.     

Changes in dormancy of Sisymbrium officinaleseeds do not depend on changes in respiratory activity

Effects of dark incubation at different temperatures were studied on dormancy and respiratory activity of seeds of Sisymbrium officinale (L.) Scop. Because germination of this species absolutely depends on the simultaneous action of light and nitrate, changes in dormancy could be studied in darkness without the interference of early germination events. Upon the start of incubation rates of O₂ uptake and CO₂ release rose. This was followed by a gradual decrease until stable levels of O₂ uptake and CO₂ release were achieved. Seeds kept for prolonged periods at 24^°C, showed neither a change in germination capacity nor in rates of O₂ uptake and CO₂ release. Respiratory quotients were 0.55–0.7. The initial rise in O₂ uptake correlated with the rate of water uptake and with breaking of primary dormancy. However, the subsequent decline in O₂ uptake was not generally linked to induction of secondary dormancy. An increased O₂ uptake was not required during breaking of secondary dormancy. It is concluded that changes in dormancy are not generally related to changes in respiratory activity. However, germination strongly depends on respiration. The increase in O₂ uptake started well before radicle protrusion. A far red irradiation only reversed this increase when it was given before germination escaped from its red light antagonising action. The contribution of different respiratory pathways was followed during prolonged incubation at 24^°C in darkness. KCN at 1.5 mM was needed to inhibit the cytochrome pathway (CP) and benzohydroxamic acid (BHAM) at 30 mM to inhibit the alternative pathway (AP). These concentrations did not exert any side effects. Electron flow was predominantly via the CP, maximally 10% was via the AP. Flow through the CP declined during the first 6 days and residual respiration remained constant. Therefore, the contribution of residual respiration became relatively more important with prolonged incubation. KCN at concentrations that almost completely inhibited flow through the CP, did not dramatically reduce germination. BHAM already inhibited germination at concentrations that do not inhibit oxygen uptake.     

Regulation of vasoactive intestinal peptide expression in sympathetic neurons in culture and after axotomy: The role of cholinergic differentiation factor/leukemia inhibitory factor

Vasoactive intestinal peptide (VIP) expression increases in sympathetic neurons when they are grown in dissociated cell or explant cultures and when they are axotomized in vivo. In dissociated cell culture, the magnitude of the VIP increase was reduced when nonneuronal cells were removed and medium conditioned by ganglionic nonneuronal cells increased VIP in neuron-enriched cultures. Antiserum Against cholinergic differentiation factor (also leukemia inhibitory factor; CDF/LIF), but not against ciliary neurotrophic factor, immunoprecipitated this activity. Medium conditioned by sympathetic ganglion explants also contained a VIP-stimulatory molecule that was immunoprecipitated by CDF/LIF antiserum, and CDF/LIF antiserum partially blocked VIP induction in explants. CDF/LIF mRNA was increased in dissociated cell cultures, in ganglion explants and in vivo after axotomy. Our results suggest that CDF/LIF released from ganglionic nonneuronal cells plays an important role in regulating VIP after axotomy. 1994 John Wiley & Sons, Inc.     

转基因微生物生态学及大田释放风险评价研究

向环境中释放转基因微生物可能会带来一系列的安全问题．在大面积释放之前必须对转基因微生物在环境中发生基因转移的潜力、存活能力、扩散能力及对生态系统的潜在影响等进行生态学研究和风险评价,同时还要探索有效的检测方法和风险评价策略．该研究有助于分子生态学的发展和生物技术的安全应用,具有重要的理论和实践意义．     

Life history and reproductive potential of the agarophyte Gelidium robustum in California

The reproductive potential of the tetrasporangial phase of Gelidium robustum was studied for 16 months at two sites off Santa Barbara, California. In all samples tetrasporangial thalli were always more abundant than gametangial ones. Tetratrasporangial sori were present throughout the duration of the study but relative fecundity was highest [300–400 sori g^–1 (w. wt)] in spring/summer samples of consecutive years, as a result of increasing numbers both of tetrasporangial branchlets per plant and of sori per branchlet. On the other hand, laboratory experiments showed that tetraspore release per sorus was highest (150–250 spores sorus^–1 d^–1) in winter. Inferring from these field and laboratory data plants released up to ± 34 000 tetraspores g^–1 (w. wt) d^–1 in the spring/summer of the second study year. Tetraspore germination, under defined culture conditions, also showed a marked seasonality increasing sharply from less than 10% in winter up to almost 60% in spring/summer, thus coinciding with the period of maximal spore output per plant. These results suggest that although relatively high numbers of tetraspores may be released by G. robustum plants all year round these might not always have the potential to germinate and recruit.