大豆根瘤菌与磷细菌混合培养下的互作效应

对研究室保藏、无拮抗作用的菌种大豆根瘤菌R12和磷细菌S7进行不同的培养处理,根据生物量及解磷量的变化,探讨二者间相互作用的效应。试验共设5个处理:R12单独培养,S7单独培养,(R12+S7)混合培养,(R12+S7单独培养后的除菌上清液)混合培养,(S7+R12单独培养后的除菌上清液)混合培养,定期测定活菌数和解磷量,结果表明,R12和S7对彼此的生长有不同的促进作用,混合培养下R12为优势菌株活菌数增加明显,S7的活菌数增长幅度较小,但对S7解磷量,混合培养和加R12单独培养后的除菌上清液较S7单独培养高出23.6%和27.8%,由此推测S7单菌解磷能力有所提高。     

根瘤菌属胞外多糖的研究

本文研究了豌豆根瘤菌(Rhizobum Leguminosarum),苜蓿根瘤菌(R. meliloti),三叶草根瘤菌(R. trifolii),菜豆根瘤菌(R. phaseoli),豇豆根瘤菌(Rradyrhizobium sp.(Vigna))和大豆根瘤菌(R. Japonicum)产生的胞外多糖化学组分的差异,结果表明,不同种的根瘤菌能产生具有不同组分的胞外多糖,其多糖组分的差异主要表现在糖醛酸和甘露糖的含量。豌豆根瘤菌、三叶草根瘤菌,菜豆根瘤菌产生的胞外多糖含有糖醛酸,大豆根瘤菌和苜蓿根瘤菌产生的胞外多糖一般不含有糖醛酸。根瘤菌有快生型和慢生型之别,这种差异也可由其产生的胞外多糖组分看到,一般快生型根瘤菌:豌豆根瘤菌,苜蓿根瘤菌,菜豆根瘤菌,三叶草根瘤菌,(包括最近证明的快生型大豆根瘤菌)的胞外多糖中甘露糖所占百分比较低(低于20％),葡萄糖所占的百分比较高(高于60％),而慢生型根瘤菌:大豆根瘤菌和豇豆根瘤菌的胞外多糖中甘露糖所占百分比较高(高于36％),葡萄糖所占的百分比较低(低于50％)。     

紫云英根瘤菌胞外多糖合成基因exol的序列分析

对互补紫云英根瘤菌ＥｘｏＮｄｖＦｉｘ变种的２．６ｋｂＤＮＡ片段进行序列测定,分析结果表明,该片段内存在的一个完整的阅读框架（ＯＲＦ）ｅｘｏｌ。ｅｘｏｌ编码了３４０个氨基酸,为细胞质蛋白。Ｅｘｏｌ蛋白序列与苜蓿根瘤菌的糖基转移酶ＥｘｏＵ有较强的同源性,利用启动子检测质粒,分析ｅｘｏｌ基因的表达,发现在ｅｘｏｌ基因上有两个启动子活性区段,Ｐｅｘｏｌａ位于基因前端,Ｐｅｘｏ１ｂ位于基因中间,Ｐｅｘｏｌａ     

根瘤菌N613胞外多糖发酵条件及抗肿瘤作用研究

用摇瓶正交试验研究了根瘤菌Rhizobium sp.N613合成根瘤菌胞外多糖(rhizobium exopolysaccharide,REPS)的最佳培养基配方和最适培养条件。采用10L自动控制罐进行了分批发酵试验,获得了合成REPS的发酵动力学参数。经40h的补料分批发酵与代谢调控,REPS产量达到11.31g/L。此外,抗肿瘤实验表明,当REPS剂量为5mg/kg时,其抑瘤率可达53.40%。结果表明,REPS的发酵周期短,产量高,成本低,且具有良好的免疫活性与增稠性,有着极高的开发应用价值。     

紫云英根瘤菌107菌株酸性胞外多糖的分离纯化及结构分析

用化学沉淀法和柱层析法,分离纯化了紫云英根瘤菌野生型１０７菌株,胞外多糖合成缺陷型变种ＮＡ０２及其回复子ＮＡ０２（Ｒ‘－１１）产生的酸性胞外多糖（ＥＰＳ）。结构组成分析表明：菌株１０７与ＮＡ０２（Ｒ’－１１）产生的ＥＰＳ糖组分均由葡萄糖、半乳糖、核糖和葡萄糖醛酸构成,而变种ＮＡ０２产生的ＥＰＳ只含葡萄糖、半乳糖和葡萄糖醛酸,与野生型显著不同。３个菌株的ＥＰＳ均有乙酰基取代,而无其它形式的取代基。Ｅ     

连锁条件下基因互作形式的判定

如何根据子代的表型判断基因互作形式,是遗传学上重要也是困难的问题.文[l～2］在自由组合条件下给出了判定方法.本文得到了基因连锁时互作形式的判定法则,它是文［l～2］的推广．     

干旱胁迫下白刺花种子大小与萌发对策

种子大小与种子萌发及其与环境因子的关系是植物种子萌发对策研究中的重要科学问题之一。采用PEG模拟干旱法研究不同干旱胁迫强度(0,5%,10%,15%,20%)下,白刺花(Sophora davidii)种子萌发进程、种子大小与种子萌发及种子命运的关系。结果表明:不同干旱胁迫下,白刺花种子具有相似的萌发进程,但中度干旱处理(10%PEG)萌发率显著高于零干旱(0%PEG)和重度干旱处理(P0.05),重度干旱处理(20%PEG)种子萌发开始时间晚于零干旱和中度干旱处理;种子大小与种子萌发开始时间的关系表现为零干旱处理下呈极显著负线性关系,中度干旱处理(5%PEG,10%PEG)下无相关关系,重度干旱处理(15%PEG,20%PEG)下呈负二次曲线关系;种子大小对种子命运的影响表现为零干旱处理有利于大、小种子萌发和小种子休眠,中度干旱处理(10%PEG)增加中等种子萌发、大种子休眠和小种子死亡风险,重度干旱处理(15%PEG,20%PEG)增加大种子死亡风险、中等种子和小种子休眠。综合分析表明,白刺花种子大小与萌发行为及种子命运的关系具有较强的环境依赖性,即种子萌发行为表现为顺境下种子越大萌发越快,逆境下小种子和大种子较中等种子萌发更快;种子命运表现为顺境增加种子死亡的风险,中度干扰有利于种子萌发,逆境则有利于种子休眠。     

乡土植物白刺花对紫茎泽兰化感作用的响应

为了解乡土植物白刺花对紫茎泽兰化感作用的耐受程度及抵御机理,以2—3年生紫茎泽兰叶片为供体材料,用不同浓度的紫茎泽兰叶片浸提液处理白刺花种子及幼苗。结果表明:紫茎泽兰叶片浸提液对白刺花的影响为低浓度促进,高浓度抑制。当浓度为0.5%时促进效应最强,当浓度大于2.0%时抑制效应明显增加。白刺花种子萌发速率比萌发率对紫茎泽兰化感作用反应敏感,胚轴比胚根敏感,随着幼苗的生长,其抵御紫茎泽兰化感作用的能力逐渐增强,丙二醛的含量与植株生长响应规律相对应,并且经紫茎泽兰浸提液处理能极大的增加白刺花幼苗菌根率,缩短菌根形成的时间。     

渗透剂对白刺花体细胞胚成熟及萌发的影响

该研究以蔗糖、麦芽糖、山梨醇及PEG(6000)为渗透剂,探讨了不同渗透剂对白刺花体细胞胚发育、胚成熟及萌发的影响。结果表明:白刺花下胚轴形成的胚性愈伤组织接种至MS+2,4-D 0.2 mg·L~(-1)+NAA 1.0 mg·L~(-1)+6-BA 2.0 mg·L~(-1)+TDZ 1.0 mg·L~(-1)+蔗糖40 g·L~(-1)+谷氨酰胺100 mg·L~(-1)+植物凝胶3g·L~(-1)的培养基上,体细胞胚发生率高达66. 21%,总胚数为79个; 7%蔗糖可使体细胞胚成熟率高达64.36%,同时也可提高多子叶畸形胚形成; 2%麦芽糖+2%山梨醇+4%蔗糖组合使体细胞胚成熟率最高达88.89%,畸形胚比例最低; 30 g·L~(-1)PEG培养时,体细胞成熟率最高,为82.35%;鱼雷期的体细胞胚最合适转接,可使体胚萌发率达90.58%,复合糖上培养得到的成熟体细胞胚生根率最高,为87.47%。这为实现白刺花体细胞胚育苗奠定了理论基础,并提供了可行的方案。     

混合盐碱胁迫下接种丛枝菌根真菌和根瘤菌对紫花苜蓿生长的影响

随着气候变化,全球土壤盐碱化严重威胁着农牧业生产和生态环境的建设。土壤盐化与碱化常常伴随发生,目前多数研究侧重于盐胁迫,忽略了碱胁迫的存在。实际上,碱性盐除了盐度外还伴随着高p H。由此,试图探讨混合盐碱胁迫下接种丛枝菌根真菌(AMF)和根瘤菌对紫花苜蓿生长的影响及其作用机理。根据中国盐碱地的特点,将4种盐(Na Cl、Na_2SO_4、Na_2CO_3、Na HCO_3)按一定比例混合模拟出16种混合盐碱(盐浓度25—150 mmol/L,p H 7.67—10.52)胁迫浓度,按照L_(16)(16~1×2~2)混合正交设计,采用盆栽法研究了混合盐碱胁迫下接种AMF摩西管柄囊霉(Funneliformis mosseae)和根瘤菌(Sinorhizobium meliloti)对紫花苜蓿生长及生理的影响。结果表明:对紫花苜蓿株高的影响程度依次是AMF+根瘤菌pHAMF盐碱类型根瘤菌;对地上生物量、地下生物量、茎高净增长量、丙二醛(MDA)及脯氨酸影响程度依次是p HAMF+根瘤菌盐碱类型AMF根瘤菌;对超氧化物歧化酶(SOD)的影响程度依次是p HAMF+根瘤菌盐碱类型AMF根瘤菌;对过氧化物酶(POD)影响程度依次是p HAMF+根瘤菌根瘤菌AMF盐碱类型;对蛋白质的影响程度依次是p H盐碱类型根瘤菌AMF+根瘤菌=AMF。株高、地下生物量、POD均在双接种的处理下出现最大值。本研究证明:盐碱混合胁迫会严重抑制植物的生长发育;而接种AMF和/或根瘤菌均可有效缓解盐碱胁迫对植物造成的伤害,提高植物对盐碱的耐受能力;且同时接种AMF及根瘤菌效果最好,其次是单独接种AMF,单独接种根瘤菌作用相对最小。     

Competition between rhizobia under different environmental conditions affects the nodulation of a legume

Mutualistic symbiosis and nitrogen fixation of legume rhizobia play a key role in ecological environments. Although many different rhizobial species can form nodules with a specific legume, there is often a dominant microsymbiont, which has the highest nodule occupancy rates, and they are often known as the “most favorable rhizobia”. Shifts in the most favorable rhizobia for a legume in different geographical regions or soil types are not well understood. Therefore, in order to explore the shift model, an experiment was designed using successive inoculations of rhizobia on one legume. The plants were grown in either sterile vermiculite or a sandy soil. Results showed that, depending on the environment, a legume could select its preferential rhizobial partner in order to establish symbiosis. For perennial legumes, nodulation is a continuous and sequential process. In this study, when the most favorable rhizobial strain was available to infect the plant first, it was dominant in the nodules, regardless of the existence of other rhizobial strains in the rhizosphere. Other rhizobial strains had an opportunity to establish symbiosis with the plant when the most favorable rhizobial strain was not present in the rhizosphere. Nodule occupancy rates of the most favorable rhizobial strain depended on the competitiveness of other rhizobial strains in the rhizosphere and the environmental adaptability of the favorable rhizobial strain (in this case, to mild vermiculite or hostile sandy soil). To produce high nodulation and efficient nitrogen fixation, the most favorable rhizobial strain should be selected and inoculated into the rhizosphere of legume plants under optimum environmental conditions.     

苦豆子的组织培养及植株再生的研究

用4种诱导培养基P1(MS+2,4-D0.5mg/L)、P2(MS+6-BA0.1mg/L+NAA0.5mg/L)、P3(MS+6-BA0.5mg/L+NAA0.5mg/L)、P4(MS+NAA1.0mg/L+KT0.5mg/L),3种分化培养基(MS+6-BA1mg/L;MS+6-BA0.5mg/L;MS+6-BA1mg/L+NAA0.2mg/L)和4种生根培养基(MS;MS+IBA1mg/L;MS+IBA1mg/L+IAA0.5mg/L;1/2MS+IAA0.2mg/L)对苦豆子愈伤组织进行诱导和植株再生,研究影响苦豆子组织培养的因素,结果表明愈伤组织的诱导频率主要依靠激素的种类和浓度,培养基中加入0.2～2mg/L的2,4-D有利于苦豆子愈伤组织生长,但使褐化发生时间提前;培养基中加入活性炭对苦豆子愈伤组织褐化有明显的抑制作用;加入IAA对苦豆子根的分化是必需的。     

Formation of pyridine nucleotides under symbiotic and non-symbiotic conditions between soybean nodules and free-living rhizobia

Enzymatic regulation of pyricline nucleotide formation, under symbiotic and non-symbiotic conditions, was analyzed using soybeans (Glycine max L. cv. 'Akisengoku') and rhizobia (Bradyrhizobia japonicum strain A1017), respectively. It was found that levels of pyridine nucleotides in bacteroids in root nodules were different from those in free-living cells of rhizobia. This difference was associated with differences in activities of enzymes involved in the pathway from L-tryptophan to NAD and NADP. That is, these activities were lower in bacteroids than in free-living bacteria and lower in the nodule cytosol than in root extracts. The optimum pH for NAD synthetase in bacteroids, was 9.0. Additionally, the optimum pH for ATP-nicotinamide mononucleotide (NMN) adenyltransferase, final step enzyme in NAD formation, was estimated to be 7.6. In the bacteroid fraction, the K(m) of NAD synthetase (22 microM) was approximately 1/22 of that of ATP-NMN adenyltransferase (482 microM). Vmax values were estimated to be almost in the same order for both NAD synthetase and ATP-NMN adenyltransferase. This is the first report on the formation of pyridine nucleotides originating from L-tryptophan in bacteroids in soybean nodules and free-living bacteria.     

不同降水条件下沙鞭种群非生殖株丛空间格局分析

植物空间分布格局是物种自身生物学特性与环境因素共同作用的结果,非生殖株丛空间分布格局能够揭示物种无性繁殖与种群扩张过程对异质生境的生态学适应机制。利用基于完全随机、泊松聚块和嵌套双聚块模型的点格局方法和群落学调查,分析了沙鞭(Psammochloa villosa)种群非生殖株丛空间分布格局,探讨了空间格局对降水梯度的响应和适应过程。结果表明：(1)聚集分布是沙鞭种群非生殖株丛的主要类型。在89 mm/a、107.8 mm/a、117.4 mm/a、186 mm/a、191.1 mm/a、363 mm/a降水梯度上聚集尺度分别为3—126 cm、9—200 cm、9—129 cm、6—77 cm、2—95 cm、2—96 cm;(2)基于完全随机模型的空间分布格局对降水的响应规律显著,整体表现为随干旱程度加剧,沙鞭种群非生殖株丛聚集尺度从2—96 cm下降至6—77 cm;(3)在107.8 mm/a、117.4 mm/a、191.1 mm/a、363 mm/a降水梯度上,基于泊松聚块模型的空间分布格局分别在15—19 cm、2—6 cm、2—4 cm、9—25 cm尺度正向偏离泊松聚...     

不同山茶种质组培条件下染色体倍性的维持与变化

植物染色体的倍性维持和变化受环境因素影响,组培再生过程由于培养条件等因素往往导致染色体的结构和倍性变化。为探索组培条件下山茶种质的倍性变化,该研究利用山茶种质的愈伤组织诱导体系,通过流式细胞仪分析倍性变化情况,并结合秋水仙素处理对组培再生条件下倍性的稳定性和变化进行分析。结果表明:(1)10个山茶种质中6个为二倍体,2个为四倍体,1个为六倍体和1个为十倍体,在组培诱导愈伤及再生过程中不同倍性的种质材料能够保持稳定的倍性。(2)获得了秋水仙素处理的最适诱导条件,即培养基配方为秋水仙素浓度20 mg·L^-1,愈伤增殖培养10 d。(3)对56个独立组织样品(含愈伤和芽)开展了倍性检测发现,有38个组织样品的倍性在1.5～2.5倍之间,11个组织样品产生了低于1.5倍性的特异现象。该研究结果进一步探索了不同山茶种质之间的倍性关系,为山茶属植物的倍性调控和多倍体诱导提供了理论基础。     

Effects of drought stress and N supply on the growth, biomass partitioning and water-use efficiency of Sophora davidii seedlings

A greenhouse experiment was conducted in order to understand the adaptation responses to different water and N conditions, and further explore if additional N supply could improve the water-use efficiency (WUE) and adaptability of Sophora davidii seedlings under dry conditions. Two-month-old seedlings were subjected to a completely random design with three water (80, 40 and 20% water field capacity (FC)) and three N supply (N0: 0, Nl: 92 and Nh:184 mg N kg⁻¹ soil) regimes. Drought stress dramatically decreased seedlings height, basal diameter, leaf number, leaf area, root length, and biomass production. An increase in below-ground biomass was observed indicating a higher root/shoot ratio (R/S) under drought stress conditions, and drought further decreased relative water content (RWC) and WUE. On the other hand, S. davidii seedlings exhibited strong responses to N supply, but the responses were inconsistent with the various N supply levels. Low N supply (Nl) increased seedlings height, basal diameter, leaf number, leaf area, and biomass production, but decreased root length. In contrast, high N supply (Nh) decreased or had little effect on these growth characteristics. N supply increased leaf percentages, but decreased fine root percentages. In addition, Nl rather than the other two N treatments increased leaf area ratio (LAR), leaf/fine root mass ratio (L/FR), R/S and RWC under severe drought stress (20% FC), even though these parameters could increase with the Nh treatment under well-watered condition (80% FC). Moreover, Nl also increased WUE under three water conditions, but Nh had little effect on WUE under drought stress conditions (40% FC and 20% FC). The results suggested that water and N co-limited the growth of S. davidii seedlings, and the seedlings exhibited great positive responses to Nl in this study. Appropriate or low N supply, therefore, would be recommended to stimulate growth, enhance WUE, alleviate drought stress, and consequently contribute to S. davidii seedling establishment under dry condition, but excess N supply should be avoided.