TDZ诱导花生幼叶的不定芽和体细胞胚发生的组织学观察

花生实生苗幼叶接种于MS TDZ 0.2mg/L NAA0.4mg/L诱导培养基上经诱导培养,继而转移到无激素培养基MS可获得不定芽和体细胞胚。组织学观察表明,花生不定芽和体细胞胚均起源于愈伤组织表层,不定芽为多细胞起源,而体细胞胚起源于单个胚性原始细胞。体细胞胚的发育经历多细胞原胚、球形胚、心形胚、鱼雷胚和子叶胚等时期发育成小植株。     

激素对百合植株再生的影响

本研究设计了 1 5种不同配比的激素组合研究 2 ,4 -D和 6 -BA对百合鳞片叶器官发生和体细胞胚胎发生的影响。结果表明 :在 MS培养基上 ,BA可诱导外植体直接分化不定芽 ,其中 1 .0～ 2 .0 mg/L BA诱导不定芽的分化频率最高 ,6 .0 mg/L BA抑制不定芽分化 ;2 ,4 -D可诱导直接体细胞胚胎发生 ,其中 4 .0 mg/L2 ,4 -D诱导体细胞胚胎发生的频率最高 ,而 6 .0 mg/L 2 ,4 -D诱导体细胞胚胎发生的频率降低 ;当培养基中同时含有 BA和 2 ,4 -D时 ,既出现不定芽 ,又出现体细胞胚。当再生苗移入无激素的 MS培养基和含有 1 .0mg/L和 2 .0 mg/L IAA的 MS培养基上时 ,只有无激素的 MS培养基有利于根的形成。此外 ,鳞片叶的大小和外植体的接种方向也影响外植体分化     

花生成熟胚胚轴的植株再生和快繁

利用正交试验筛选出了以花生成熟胚胚轴为外植体获得较高频率的不定芽分化和植株再生的条件,并在此基础上对花生试管苗的快速繁殖进行了研究,研究表明,4d龄实生苗的花生胚轴,接种于MS NAA0.4mg/L TDZ0.2mg/L诱导培养基上培养28d后,转移到MSo可获得丛生的再生苗。将丛生苗分离,接种到P1培养基（MS NAA0.4mg/L BAP0.5mg/L）,小苗长大,把较大的试管苗切成带叶节的茎段,接种于含不同浓度的TDZ和BAP的快繁培养基,结果表明,TDZ0.2mg/L最适宜试管苗的快繁,繁殖系数可达4.8/月,试管苗经IBA诱导生根后,移栽田间,开花结果。     

白刺花胚性愈伤组织诱导及体细胞胚发生和萌发

探讨不同因素对白刺花下胚轴、子叶2种外植体胚性愈伤组织诱导及体细胞胚发生和萌发的影响。以B5和MS为基本培养基,研究2,4-D、6-BA和TDZ对白刺花下胚轴和子叶胚性愈伤组织的诱导;在MS培养基上添加不同浓度2,4-D,研究胚性愈伤组织增殖情况;采用ABA,探究对体细胞胚发生的影响。结果表明:下胚轴比子叶更易诱导胚性愈伤组织,筛选出2种外植最佳的胚性愈伤组织诱导培养基均为MS+2.0 mg/L 2,4-D+0.5 mg/L TDZ+0.5 mg/L 6-BA,胚性愈伤组织诱导率分别为77.3%和41.0%。15.0 mg/L ABA、0.2 mg/L 2,4-D和2.0 mg/L 6-BA有利于体细胞胚发生,1/3MS+0.2 mg/L NAA+0.1 mg/L 6-BA+2.0 g/L活性炭+25 g/L蔗糖+7 g/L琼脂的培养基可使体细胞胚萌发率达80%以上,再生植株移栽成活率高达90%。白刺花外植体种类及培养基类型均会影响胚性愈伤组织的诱导,其中下胚轴诱导效果优于子叶;MS培养基较适合启动细胞脱分化形成愈伤组织,2,4-D对胚性愈伤组织的增殖保持有调控作用,ABA有利于体细胞胚的发生。     

如意皇后粗肋草愈伤组织及丛生芽诱导培养基优化

本研究以粗肋草‘Red Valentine’带侧芽的根茎为外植体,研究不同培养基类型、不同外源激素及浓度、不同转接周期对其愈伤组织及丛生芽诱导的影响,进而优化如意愈伤组织和丛生芽诱导培养基。结果表明:最佳愈伤组织诱导培养基为MS+0.5 mg/L TDZ+2.0 mg/L 2,4-D和1/2MS+0.5 mg/L TDZ+2.5 mg/L 2,4-D;最佳愈伤组织分化培养基为1/2 MS+0.4 mg/L TDZ,最佳转接周期为30 d;最佳丛生芽诱导培养基为5.0 mg/L6-BA+0.2 mg/L NAA和1/2 MS+0.5 mg/L TDZ,最佳转接周期为30 d。优化培养基后愈伤组织及丛生芽诱导效率更高。本研究通过设计优化试验,筛选出了愈伤组织诱导及丛生芽诱导的最佳培养基,为粗肋草属植物的快速繁殖及规模化生产提供了一定的理论指导。     

‘SK4—316’胡萝卜体胚的诱导和培养

以'SK4-316'胡萝卜无菌苗的下胚轴为外植体,研究不同培养基配方和培养条件对愈伤组织诱导、体细胞胚间接发生及其同步化培养的影响,以及不同脱分化时间、脱分化培养基及外植体续存时间对体细胞胚直接发生的诱导及其培养的影响.结果表明:含3%蔗糖、0.8%琼脂的1/2MS + 2,4-D 2.5 mg/L + 6-BA(或KT)0.5 mg/L + CH 300 mg/L是诱导愈伤组织的良好培养基;1/2MS + 2,4-D 1.25 mg/L + KT 0.25 mg/L + 6-BA 0.25 mg/L(含3%蔗糖)适于愈伤组织分化并诱导体胚发生,0.02% ABA对体胚的诱导有促进作用,0.06% ABA或15% PEG能促进体胚成熟;外植体在MS + 2,4-D 1.0 mg/L固体培养基上脱分化培养48 h,再转入MS + CH 300 g/L液体培养基中可诱导体胚直接发生,但随着外植体续存于诱导培养基中时间的延长,体胚发生变异的几率也渐增.     

"东湖早"枇杷的组织培养(简报)

以“东湖早”枇杷的幼胚为外植体,在B5 2,4-D 0.5 mg/L 6-BA 1.0 mg/L培养基上诱导愈伤组织,经继代培养基B5 2,4-D 0.1 mg/L 6-BA 0.5 mg/L培养后,置于B5 6-BA 1.5 mg/L培养基上诱导分化,产生不定芽。将幼苗切段转接到MS 6-BA 2.0 mg/L NAA 0.5 mg/L培养基上进行增殖培养,繁殖系数为3~5。待芽长2~3cm时再分切成单株于1/2MS NAA 0.5 mg/L培养基上,可正常生根。     

党参的离体培养及植株再生的研究

在附加激素的MS培养基上,培养党参下胚轴和无菌芽切段,诱导产生愈伤组织并且再生植株。经过两年多(15个世代)的继代培养,建立了党参体细胞无性系。实验结果表明:(1)培养基MS 0.4mg/L 2,4-D 0.8mg/L Kt 2.0mg/L IAA对愈伤组织诱导及继代培养,MS 0.2mg/L 6-BA诱导外植体产生丛芽和愈伤组织再分化,MS 0.5mg/L NAA 0.2mg/L 6-BA及MS 0.2mg/L NAA诱导生根效果最好。(2)愈伤组织再分化经过胚状体途径。     

2,4-D浓度对花生体细胞胚发生的影响

选用丰花2号、鲁花11和农大818三个花生品种的胚小叶为外植体,在MSB培养基中分别添加不同浓度的2,4-D(1、5、10、15、20ms／L)作为诱导培养基,以MSB为继代培养基,研究2,4-D浓度对花生体细胞胚胎发生的影响。结果表明：2,4-D浓度对花生胚小叶脱分化及再分化有显著影响,低浓度的2,4-D对外植体脱分化有利,而较高浓度对再分化有利,诱导体细胞胚的最适2,4-D浓度为15mg／L。不同品种的体细胞胚诱导频率存在差异,丰花2号和农大818比鲁花11的体细胞胚诱导频率高;且丰花2号的成苗能力较强,在MSB培养基上即可成苗,鲁花11及农大818成苗能力较差。     

植物生长调节剂对白头翁叶片培养的影响

以白头翁试管苗叶片为外植体,以MS为基础培养基,探讨不同细胞分裂素和生长素对叶片不定芽诱导、愈伤组织的诱导、增殖、再分化的影响。实验结果表明：细胞分裂素TDZ适合于白头翁叶片培养,与生长素搭配使用使叶片发生分化;2,4-D对愈伤组织的诱导能力相对较强。叶片直接诱导不定芽的激素组合为TDZ0．3mg／L＋NAA0．1mg／L;愈伤组织增殖的激素组合为TDZ0．2mg／L＋2,4-D0．2mg／L,将愈伤组织转接到TDZ和NAA组合的培养基上时会再分化。     

Investigation of the mechanism of temperature sensitivity of the electroreceptors of ampullae of lorenzini

In experiments on Black Sea skates (Raja clavata), the potential of the receptor epithelium of the ampullae of Lorenzini and spike activity of single nerve fibers connected to them were investigated during electrical and temperature stimulation. Usually the potential within the canal was between 0 and –2 mV, and the input resistance of the ampulla 250–400 k. Heating of the region of the receptor epithelium was accompanied by a negative wave of potential, an increase in input resistance, and inhibition of spike activity. With worsening of the animal's condition the transepithelial potential became positive (up to +10 mV) but the input resistance of the ampulla during stimulation with a positive current was nonlinear in some cases: a regenerative spike of positive polarity appeared in the channel. During heating, the spike response was sometimes reversed in sign. It is suggested that fluctuations of the transepithelial potential and spike responses to temperature stimulation reflect changes in the potential difference on the basal membrane of the receptor cells, which is described by a relationship of the Nernst's or Goldman's equation type.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. I. M. Sechenov, Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Pacific Institute of Oceanology, Far Eastern Scientific Center, Academy of Sciences of the USSR, Vladivostok. Translated from Neirofiziologiya, Vol. 12, No. 1, pp. 67–74, January–February, 1980.     

Shapes of curves of pH-dependence of reactions

A simple case is considered in which the rate of a two-step reaction depends on pH because the intermediate formed in the first step has to gain (or lose) a proton before it can react in the second step, and in which the rate-determining step therefore changes with pH. The curves of reaction rate against pH are shown to be symmetrical, and the sharpest peak possible has a width at half its height of 1.53pH units, i.e. of 2log(3+2 radical2). Any particular curve for this situation proves to be identical with a curve that could be generated for the pH-dependence of a single-step reaction in which the rate is proportional to the concentration of a particular ionic form of a reactant. Curves for the latter situation, however, can have forms impossible for the former case in which the rate-determining step changes, but only if the protonations that activate and deactivate the reactant are co-operative. The peak can then become even sharper, and its width at half its height can fall to 1.14pH units, i.e. to 2log(2+ radical3).     

Overview of mechanisms of action of lycopene

Dietary intakes of tomatoes and tomato products containing lycopene have been shown to be associated with decreased risk of chronic diseases such as cancer and cardiovascular diseases in numerous studies. Serum and tissue lycopene levels have also been inversely related to the risk of lung and prostate cancers. Lycopene functions as a very potent antioxidant, and this is clearly a major important mechanism of lycopene action. In this regard, lycopene can trap singlet oxygen and reduce mutagenesis in the Ames test. However, evidence is accumulating for other mechanisms as well. Lycopene at physiological concentrations can inhibit human cancer cell growth by interfering with growth factor receptor signaling and cell cycle progression specifically in prostate cancer cells without evidence of toxic effects or apoptosis of cells. Studies using human and animal cells have identified a gene, connexin 43, whose expression is upregulated by lycopene and which allows direct intercellular gap junctional communication (GJC). GJC is deficient in many human tumors and its restoration or upregulation is associated with decreased proliferation. The combination of low concentrations of lycopene with 1,25-dihydroxyvitamin D3 exhibits a synergistic effect on cell proliferation and differentiation and an additive effect on cell cycle progression in the HL-60 promyelocytic leukemia cell line, suggesting some interaction at a nuclear or subcellular level. The combination of lycopene and lutein synergistically interact as antioxidants, and this may relate to specific positioning of different carotenoids in membranes. This review will focus on the growing body of evidence that carotenoids have unexpected biologic effects in experimental systems, some of which may contribute to their cancer preventive properties in models of carcinogenesis. Consideration of solubility in vitro, comparison with doses achieved in humans by dietary means, interactions with other phytochemicals, and other potential mechanisms such as stimulation of xenobiotic metabolism, inhibition of cholesterogenesis, modulation of cyclooxygenase pathways, and inhibition of inflammation will be considered. This review will point out areas for future research where more evidence is needed on the effects of lycopene on the etiology of chronic disease.