薯蓣皂素对油菜种子萌发及幼苗生长的影响

薯蓣皂素对油菜种子萌发及幼苗生长的作用随处理浓度的不同而有差别。0．5mg／L对种子萌发和幼苗生长有明显的促进作用,处理后的油菜幼苗下胚轴伸长,干鲜重增加,并且子叶中可溶性蛋白、可溶性总糖、过氧化物酶和过氧化氢酶、Ca2 -ATP酶的活性都高于对照,这表明适度的薯蓣皂素有利于油菜生长和代谢。     

Cumulative activation of axillary buds by nodal roots in Trifolium repens L

In Trifolium repens the rate of outgrowth of an axillary bud was closely correlated with its duration of exposure to a nearby nodal root. The dose-dependent nature of this relationship, over 0-22 d, is consistent with the concept that axillary buds are cumulatively activated by a root signal (RS) such that the longer they receive the signal the higher is their level of activation and hence their rate of outgrowth. Furthermore, the activation level attained by a bud was subsequently retained following the excision of the nodal root providing the source of its activation: its rate of growth 3-6 weeks after root excision still reflected the initial level of activation of the bud. Thus, once activated, a bud required relatively little RS to maintain its rate of outgrowth, implying that activation involves the establishment of an autonomous control mechanism within the bud itself. This provides an explanation of how a strongly activated apical bud can continue growth at relatively low RS levels when it is distanced from its nearest root system, while at the same time the prevailing low RS environment leads to weak activation of the axillary buds emerging from it.     

Distribution and Function of Proteoid Roots and other Root Clusters

Proteoid roots are bottlebrush-like clusters of rootlets which form along lateral roots. They are characteristic of most species of the Proteaceae, which are mainly distributed in Australia and South Africa. Homologous root clusters are present in species of the Casuarinaceae, Mimosaceae, Fabaceae, Myricaceae and Moraceae. Many similarities exist between these species in relation to morphology and function of root clusters. Many are non-mycorrhizal and are highly efficient in phosphorus (P) acquisition. In these species, proteoid roots and proteoid-like root clusters are abundant when grown on infertile soils. Their formation is predominantly affected by the P status of the plants, being induced at low P levels and repressed at high P levels. Proteoid roots and proteoid-like root clusters play an important role in acquisition of P and other mineral nutrients. Although increase in root surface area may be a contributing factor, in many species these roots excrete large amounts of organic acids and phenolics. The excretion of these compounds in a small soil volume gives rise to extensive nutrient mobilization by acidification, reduction and chelation of sparingly soluble forms of P and micronutrients such as Fe and Mn.     

除虫菊发状根的诱导及培养条件优化

以除虫菊（Pyrethrum cinerariifolium Trey.）无菌苗为外植体,研究除虫菊发状根的诱导、培养条件优化,并对发状根中的除虫菊素进行检测和生物活性测定。结果显示,乙酰丁香酮能促进除虫菊下胚轴和子叶发状根的诱导,当乙酰丁香酮浓度为150 μmol/L时除虫菊下胚轴和子叶的诱导率为对照的2.29倍和2.66倍,预培养6 d时,下胚轴发状根诱导率为对照的2.25倍,发根农杆菌A4的诱导率均高于ATCC15834,愈伤组织较适合发状根的诱导,愈伤组织侵染后适合在无激素的MS培养基上进行发状根诱导,250 mL三角瓶中添加50 mL MS培养基较适合发状根的生长。对除虫菊发状根进行PCR检测发现,发根农杆菌含有的Ri T-DNA的rolB基因已整合进入发状根基因组中。通过GCMS检测发现,愈伤组织中除虫菊素的6种成分均未检测到,而发状根中检测到瓜菊素Ⅰ、茉酮菊素Ⅰ和茉酮菊素Ⅱ 3种成分,发状根对粘虫的拒食作用明显优于愈伤组织。本研究为通过组织培养方式生产除虫菊素奠定了基础。     

蔗糖和光对三裂叶野葛毛状根生长及次生物质产生的影响

研究了蔗糖浓度和光对固体培养的三裂叶野葛毛状根生长及其总异黄酮和葛根素产生的影响。结果表明：在供试的分别添加1%、3%、5%、7%和9%蔗糖的MS固体培养基中,3%蔗糖能促进三裂叶野葛毛状根的生长及其异黄酮类化合物和葛根素的积累;培养20d后,其生物量达到0.48g(DW,干重)/瓶,总异黄酮和葛根素含量分别为25.44mg/g(DW)和11.64mg/g(DW)。与添加3%蔗糖的MS培养基培养的三裂叶野葛毛状根相比,含5%蔗糖的培养基培养的毛状根干重增殖倍数提高了7.0％,而含1％、7％和9％蔗糖的培养基培养的毛状根干重增殖倍数分别下降62.4％、42.8％和65.3％;其总异黄酮含量分别降低574％、13％和33.4％,葛根素含量分别下降47.9％、15.8％和35.1％,但其毛状根培养物的可溶性糖含量则分别增加了0.52、1.45和1.54倍。暗培养30d的毛状根的生物量达到0.83g(DW)/瓶,分别比蓝光和白光培养的毛状根提高37.1%和23.3%。在蓝光和白光下培养的部分毛状根的表面呈淡绿色;但白光处理的毛状根中总异黄酮含量比蓝光和暗培养处理的分别提高了14.7%和19.2%;蓝光抑制毛状根中葛根素含量的积累,白光和暗培养的毛状根培养物中的葛根素含量分别是蓝光处理的1.61倍和1.52倍。     

Diterpenes from the Roots of Oryza sativa L. and Their Inhibition Activity on NO Production in LPS‐Stimulated RAW264.7 Macrophages

Two new pimarane diterpenoids, momilactone D ( 3 ) and momilactone E ( 5 ), along with three known diterpenoids, momilactone A ( 1 ), sandaracopimaradien‐3‐one ( 2 ), and oryzalexin A ( 4 ) were isolated from Oryza sativa roots. The chemical structures of the compounds were determined by spectroscopic data analysis. The isolated diterpenoids were evaluated for their ability to inhibit NO production and iNOS mRNA and protein expression in LPS‐stimulated RAW264.7 macrophages. Compound 4 showed strong inhibition activity on NO production, and compounds 1 and 4 decreased the expression of iNOS mRNA and protein levels.     

干旱胁迫对东方百合根叶生理功能及花粉育性的影响

以东方百合‘Sorbonne’为材料,在持续干旱4、8、12、16、20、24d及干旱24d后复水4d时分别取样,检测叶片叶绿素荧光参数、光合生理指标、抗氧化酶活性和丙二醛含量,并观测其茎生根发育情况以及调查植株在干旱胁迫期、复水期、开花期的花粉育性,明确干旱胁迫对百合根、叶生理功能及花粉育性的影响,探讨百合的抗旱生理机制。结果表明:(1)与对照相比,干旱处理组百合植株的叶绿素含量随着干旱时间延长而逐渐降低,处理4d后百合开始明显受到干旱胁迫;胁迫4~8d内,光合作用受到的胁迫主要是气孔因素所致;胁迫8~12d期间,叶片荧光叶绿素指标开始急剧变化,光合作用受到的胁迫已开始从气孔因素转变为非气孔因素;胁迫12d后,叶片丙二醛含量增加,膜质开始受到氧化;胁迫16d时,叶片抗氧化酶系统活性达到峰值,随后开始降低,丙二醛累积随之增加,膜脂过氧化作用加剧;胁迫24d时,叶片光合指标略有所恢复。(2)解除干旱胁迫复水4d后,百合叶片光合生理指标均有所恢复,但未恢复到胁迫前水平。(3)与正常对照相比,经历干旱胁迫的百合根系随着干旱胁迫时间的延长先缩短变粗、数量减少,然后逐渐褐化并趋近萎缩,且根系干鲜重显著降低,但花粉育性在胁迫期、复水期及开花期没有显著变化。研究发现:持续24d的干旱胁迫会对东方百合叶片的光合功能和抗氧化酶系统以及根系产生破坏性的伤害,但对花粉的育性没有影响。     

Nitric Oxide is Involved in the <Emphasis Type="Italic">Azospirillum brasilense</Emphasis>-induced Lateral Root Formation in Tomato

Azospirillum spp. is a well known plant-growth-promoting rhizobacterium. Azospirillum-inoculated plants have shown to display enhanced lateral root and root hair development. These promoting effects have been attributed mainly to the production of hormone-like substances. Nitric oxide (NO) has recently been described to act as a signal molecule in the hormonal cascade leading to root formation. However, data on the possible role of NO in free-living diazotrophs associated to plant roots, is unavailable. In this work, NO production by Azospirillum brasilense Sp245 was detected by electron paramagnetic resonance (6.4 nmol. g^–1 of bacteria) and confirmed by the NO-specific fluorescent probe 4,5-diaminofluorescein diacetate (DAF-2 DA). The observed green fluorescence was significantly diminished by the addition of the specific NO scavenger 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (cPTIO). Azospirillum-inoculated and noninoculated tomato (Lycopersicon esculentum L.) roots were incubated with DAF-2 DA and examined by epifluorescence microscopy. Azospirillum-inoculated roots displayed higher fluorescence intensity which was located mainly at the vascular tissues and subepidermal cells of roots. The Azospirillum-mediated induction of lateral root formation (LRF) appears to be NO-dependent since it was completely blocked by treatment with cPTIO, whereas the addition of the NO donor sodium nitroprusside partially reverted the inhibitory effect of cPTIO. Overall, the results strongly support the participation of NO in the Azospirillum-promoted LRF in tomato seedlings.     

Causes and consequences of plant-associated biofilms

The rhizosphere is the critical interface between plant roots and soil where beneficial and harmful interactions between plants and microorganisms occur. Although microorganisms have historically been studied as planktonic (or free-swimming) cells, most are found attached to surfaces, in multicellular assemblies known as biofilms. When found in association with plants, certain bacteria such as plant growth promoting rhizobacteria not only induce plant growth but also protect plants from soil-borne pathogens in a process known as biocontrol. Contrastingly, other rhizobacteria in a biofilm matrix may cause pathogenesis in plants. Although research suggests that biofilm formation on plants is associated with biological control and pathogenic response, little is known about how plants regulate this association. Here, we assess the biological importance of biofilm association on plants.     

Comparison of the effects of kanamycin and geneticin on regeneration of papaya from root tissue

Kanamycin and geneticin are commonly used for the selection of neomycin phosphotransferase II (npt II) transformed plants. Since papaya tissue is sensitive to both antibiotics, it is difficult to explore their effects on the regeneration process solely based on using non-transformed tissues. Adventitious roots derived from npt II-transgenic and non-transgenic papaya shoots in vitro were used as explants in this investigation. The effects of kanamycin and geneticin on callus formation, embryogenesis, and conversion of somatic embryos to shoots were compared. Callus growth derived from npt II-transformed root explants was apparently enhanced on kanmycin within 50–200 mg l^–1 or on geneticin within 12.5–50 mg l^–1 as compared to those on antibiotic-free controls. The percentages of npt II-transformed somatic embryo-forming callus were not significantly different (16.3–18.3%) on geneticin less than 6.25 mg l^–1 and only slightly reduced (11.2–15.7%) on geneticin within 12.5–50 mg l^–1, whereas, formation of somatic embryos was strongly suppressed on kanamycin media. Conversion rates of npt II-transformed somatic embryos to shoots were not significantly different among all kanamycin or geneticin treatments. Percentages of the callus derived from non-transformed root explants were greatly reduced on the medium containing more than 25 mg l^–1 kanamycin or geneticin, and no somatic embryos formed from untransformed callus on any kanamycin or geneticin media. Our results indicated that somatic embryogenesis of callus derived from npt II-transformed root explants of papaya was strongly inhibited by kanamycin. Thus, to regenerate npt II-transformed cells from papaya root tissue, we recommend using the lower concentration geneticin (12.5–25 mg l^–1) to avoid the adverse effects of kanamycin on embryogenesis.