金属离子对酵母胞内核黄素产量的影响

研究了金属离子对脆壁酵母 (Saccharomycesefragilis)RY 5胞内核黄素积累的影响 ,运用均匀设计方法进行了培养基优化。结果表明 :Mg2 + ,Zn2 + ,Fe2 + 对RY 5的核黄素产量有着显著影响 ,培养基中金属离子的最佳浓度为 :MgSO4·7H2 O 1 .1g/L ;CoSO4·7H2 O 2 8mg/L ;CuSO4·5H2 O 0 .0 1mg/L ;MnCl2 0 .0 2mg/L ;ZnSO4·7H2 O 3 4mg/L ;FeSO4·7H2 O 1 4mg/L ,RY 5的核黄素产量可达 1 40mg/kg。     

拉曼被孢霉F5发酵生产γ-亚麻酸的研究

对拉曼被孢霉突变株F5发酵生产γ-亚麻酸的最适碳源、氮源、发酵时间及温度、无机盐离子添加、最适碳源浓度及补加碳源时间等发酵条件进行了研究探讨.最适发酵培养基组成为(g/L):葡萄糖100,酵母浸出粉4,蛋白胨1,K2HPO4 1,CaCl2 1×10-2,MgSO45×10-2,FeSO4 1×10-2,ZnSO4 7.5×10-3,CuSO4 0.5 × 10-5,MnSO4 2×10-3,pH 6.0.培养温度为25℃,140r/min振荡培养10天,培养8天后(即收获前2天)补加5%葡萄糖.发酵结果为:DC24.59g/L,TL 10.84g/L,TL/DC44.09%,GLA/TL10.67%,GLA产量为1156.63 mg/L. GLA产量较初始结果提高156.15%.该菌株已达到工业化生产菌株要求.     

仙鹤藓属（Atrichum）藓类植物组织培养再生体系的建立

报道了仙鹤藓（Atrichum undulatum(Hedw.)P.Beauv.)和仙鹤藓小形变种（Atrichum undulatum var.minus(Hedw.)Par.)的组织培养再生体系的建立。为研究仙鹤藓属（Atrichum)藓类愈伤组织的诱导和再分化,将仙鹤藓和仙鹤藓小形变种原丝体接种在含有4%葡萄糖和0.2-2.0mg/L 6-BA的MS培养基上,培养一个月后,成功地诱导出疏松、易碎的绿色愈伤组织。愈伤组织诱导和常规继代培养较适合的培养基为含4%葡萄糖和1-2mg/L 6-BA的MS培养基。当将继代培养5次的脱分化藓类愈伤组织转移到含4%葡萄糖但无任何激素的MS培养基上时,能再分化形成原丝体,而在无任何碳源的Benecke培养基土培养时,能再分化形成经原丝体阶段发育来的直立配子体。     

短叶对齿藓组织培养的研究

以采自白云鄂博主矿区的短叶对齿藓为试验材料,研究了不同消毒剂以及不同浓度植物激素6-BA和IAA对短叶对齿藓愈伤组织诱导和分化的影响。结果表明:短叶对齿藓配子体最佳消毒剂及作用时间为体积浓度百分比75%乙醇浸泡30s,再用质量浓度0.1g/L升汞消毒90s;采用Knop培养基培养短叶对齿藓茎叶段,质量浓度为0.1mg/L 6-BA促进愈伤组织分化形成配子体,质量浓度1.0mg/L 6-BA则抑制短叶对齿藓愈伤组织形成,IAA有助于原丝体的萌发生长。     

梨蒴珠藓愈伤组织诱导和配子体再生研究

以梨蒴珠藓无菌藓株为外植体诱导愈伤组织和配子体再生,接种于含不同激素组合的MS和Knop固体培养基上,分别进行愈伤组织和不定芽的分化,并探讨愈伤组织诱导和配子体再生的适宜培养条件.结果显示,愈伤组织诱导的最佳培养基是MS+0.5 mg/L BA+0.1 mg/L 2,4-D,愈伤组织诱导率为33.3%;不定芽诱导的最佳...     

枸杞髓组织培养中体细胞胚胎发生与过氧化物酶同工酶分析

枸杞髓组织在 MS+6 - BA0 .1mg/ L+NAA0 .5mg/ L培养基上诱导愈伤组织发生。在 MS+6 - BA0 .1mg/ L+NAA0 .5mg/ L+CH50 0 mg/ L培养基上继代培养 ,再转入 MS+6 - BA2 mg/L +NAA 0 .5mg/ L的分化培养基上进行分化培养。显微观察表明 ,在培养过程中愈伤组织细胞由非胚性细胞转变为胚性细胞 ,直至发育成体细胞胚胎和完整植株 ;电泳结果显示 ,体细胞胚胎发生的各阶段 ,其过氧化物酶同工酶发生相应的变化。     

八角莲组织培养研究

以八角莲种子为外植体,MS为基本培养基,通过不同的激素种类和浓度配比,对八角莲进行组织培养研究。结果表明:种子在MS+BA1.0mg/L+IBA0.5mg/L+GA34.0mg/L培养基上容易萌芽,发芽率为72.4 %;培养基MS+BA10.0mg/L+GA30.5 mg/L可诱导种子幼苗形成丛生芽;继代繁殖在MS+BA(8.0～10 .0)mg/L+GA32 .0mg/L与低浓度BA或无BA的培养基上进行循环培养效果较好;MS+NAA1.0 mg/L+AC0.2g/L适宜诱导生根获得再生植株,生根率100%。带叶叶柄在MS+BA1.0mg/L+2-ip(0.5～1.0) mg/L+NAA0.02 mg/L培养基上可诱导愈伤及根,直接形成再生植株。生根苗移栽成活率90 %。     

多叶斑叶兰繁殖体系建立及基于转录组的发育调控途径功能基因研究

多叶斑叶兰,是兰科斑叶兰属濒危野生植物、国家二级保护植物,具有极高的观赏和药用价值。多叶斑叶兰由于分布种群小,传播扩散能力弱,自然繁殖受到极大限制。以野生多叶斑叶兰茎段作为外植体,建立高效直接的植株再生体系。结合高通量转录组测序技术与生物信息学分析技术,深入挖掘参与多叶斑叶兰器官发育过程的功能基因。结果表明,Morel+2. 0 mg/L 6-BA+0. 5 mg/LKT+1. 0 mg/LNAA+1g/L蛋白胨+25g/L蔗糖+7. 0 g/L Agar+1. 0 g/L活性炭+30 g/L香蕉+50 g/L土豆为最佳的芽诱导培养基; Morel+3 mg/L 6-BA+0. 5mg/L NAA+0. 5mg/LKT+0. 01 mg/L TDZ+2g/L蛋白胨+25g/L蔗糖+7. 0 g/L Agar+1. 0 g/L活性炭30g/L香蕉+50g/L土豆为最佳芽增殖培养基; 1/2 Morel+1. 0 mg/L IBA+0. 1 mg/L NAA+1 g/L+花宝2号+25g/L蔗糖+7. 0g/L Agar+1. 0 g/L活性炭+1g·L-1蛋白胨为最佳的生根培养基。转录组测序分析组装获得170688个Unigene,平均长度为584 bp,N50为833 bp。17352个Unigene比对注释到NR、Swiss-Prot、KOG、GO、KEGG数据库。野生苗与组培苗差异表达Unigene GO与KEGG功能富集分析显示,Unigene主要参与调控植物激素信号转导、植物形态发育、次生代谢过程以及能量代谢过程等生物学功能。进一步分析获得511个参与植物器官发育调控相关的转录因子。成功建立了多叶斑叶兰种质资源保存与高效离体再生体系,结合高通量转录组学技术,获得全面完整的多叶斑叶兰转录组信息特征,为后期多叶斑叶兰快速扩繁、遗传转化以及功能基因鉴定、遗传发育及其调控机制研究奠定基础。     

药用植物川东獐牙菜的组织培养

针对川东獐牙菜野生资源受到严重破坏的情况 ,系统地探讨了通过组织培养为手段进行人工繁殖的方法 ,旨在为川东獐牙菜的保护提供坚实的理论依据。研究结果表明 :在所有的实验方案中 ,幼茎和老叶是理想的外植体材料。对叶片来说 ,较适宜的诱导愈伤组织的激素组合是 Zt1.0 m g/L +NAA 0 .0 5m g/L +IBA0 .0 5mg/L、BA 0 .5m g/L+2 ,4 - D0 .5mg/L或 BA 0 .2 m g/L+2 ,4 - D0 .2 mg/L+IBA0 .1m g/L ,对茎段来说 ,较适宜的诱导愈伤组织的激素组合是 BA0 .0 5m g/L+kt0 .0 5mg/L+IBA0 .0 5m g/L;诱导不定芽的适宜激素组合是 BA2 .0 mg/L+N AA0 .0 5mg/L或 BA 2 .0 mg/L+IBA 0 .1m g/L ;而根的诱导则是 MS+BA 0 .0 5mg/L+kt1.0 mg/L+N AA0 .1m g/L或 MS+BA1.0 m g/L+kt0 .3mg/L +IA A0 .5mg/L培养基上进行。     

青霉菌m8产胞外木聚糖酶的纯化及其性质研究

青霉菌m8产胞外木聚糖酶的适合培养基 (g/L) :含麦草粉 4 0 ,(NH4) 2 SO44.5 ,KH2 PO41.0 ,MgSO4·7H2 O 0 .5 ,NaCl 0 .3,Tween80 3.0 ,CaCO3 1.0。培养物中该酶经过离子交换和分子筛层析两步处理 ,粗酶被浓缩了 31倍 ,比活力达 4 6 7,收率为 5 0 %。该酶的最适 pH值为 4 .5 ,最适反应温度为 5 5℃ ,可被K+ ,Ca2 + ,Mg2 + 离子激活 ,而被Ag+ ,Fe3 + 和Cu2 + 离子纯化 ,其Km值为 4 .8× 10 -2 g/L。     

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.