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11.
菠萝DNA的提取及AFLP反应体系的建立   总被引:12,自引:2,他引:12  
为了应用AFLP分子标记对菠萝种资源进行种质鉴定、分类及亲缘关系等方面的研究,最重要的是要获得高质量的DNA,菠萝叶片革质化程度较高,且纤维、多糖、多酚等次生代谢物质含量较多,严重干扰DNA的抽提或影响其后的AFLP双酶切及其扩增反应,本研究以菠萝叶片为材料,利用改良CTAB法得到了39个高质量的菠萝分类群的DNA基因组,并进行了AFLP分析,得到了条带清晰、多态性好的菠萝品种指纹图谱,这为菠萝基因库的建立、优良品种选育以及亲缘关系的系列研究提供理论依据。  相似文献   
12.
对湖南湘潭锰矿矿业废弃地营造林的3.5-4.5年生栾树、杜英混交林进行了生物量研究.结果表明:林分密度为3 240株/hm2,栾树单株生物量为1 175-1 958 g,杜英为544-909 g;林分生物量为3125-5211.00 kg/hm2,林分净生产量为893.00- 2085.48 kg/(hm2·a).现林木生命力强,生长旺盛,林分生产潜力大.为矿区废弃地的植物修复提供了优良树种.  相似文献   
13.
[目的]探讨添加不同浓度激素及其组合培养基对海南菜豆树芽诱导、增殖和生根的影响,为建立海南菜豆树组培快繁体系提供参考依据.[方法]以海南菜豆树幼嫩茎段为外植体,以MS为基本培养基,添加不同浓度6-BA及6-BA与NAA、IBA和NAA组合,进行诱导萌芽、增殖、生根培养研究,分析添加不同浓度激素及其组合的培养基对海南菜豆树组织培养的效果.[结果]海南菜豆树芽的诱导率随6-BA质量浓度的增加而提高,当6-BA质量浓度为4.0mg/L时,芽诱导率达100.0%,且长势良好;当6-BA质量浓度为3.5 mg/L、NAA质量浓度为0.2 mg/L时芽增殖率最高,增值系数达5.8;在生根培养中,当NAA质量浓度为0.2 mg/L、IBA质量浓度为0.3 mg/L时生根率最高,达76.0%.[结论]海南菜豆树最适芽诱导培养基为MS+6-BA 4.0 mg/L;增殖培养以MS+6-BA 3.5 mg/L +NAA 0.2 mg/L效果最好;生根培养以MS+IBA 0.3 mg/L +NAA 0.2 mg/L效果最佳.  相似文献   
14.
以3 种茜草科药用植物鸡屎藤也Paederia scandens (Lour.) Merr.页、剑叶耳草(Hedyotis caudatifolia Merr. et Metcalf)、玉叶金花(Mussaenda pubescens L.)为试材,采用乙醇提取的方法制备不同浓度的乙醇提液,通过测定其对受 体萝卜(Raphanus sativus L.)发芽率、根系活力、叶片游离脯氨酸和叶绿素含量的影响,比较化感作用强弱。结果表明院 不同供试植物乙醇提液其化感效应不同,且浓度高时,化感作用强;供试植物乙醇提液均显著降低了萝卜发芽率、发芽 速率指数,且剑叶耳草在这两个指标的抑制作用显著高于另二者;供试植物乙醇提液均极显著抑制萝卜胚根和胚芽的 生长,其中鸡屎藤乙醇提液抑制胚芽的作用最强,玉叶金花提液抑制胚根的作用最强;鸡屎藤比玉叶金花更显著地抑 制萝卜幼苗根系活力,然而剑叶耳草却显著地促进;供试植物乙醇提液显著降低萝卜幼苗叶绿素含量,显著提高叶片 脯氨酸含量;鸡屎藤乙醇提液使叶绿素含量减少69.47%耀87.00%,且叶绿素a辕叶绿素b 随处理浓度的增加而降低。  相似文献   
15.
目前我国被发现或被利用于优良紫胶虫种4号胶虫(Kerria lacca)的优良寄主植物种类较少,制约了我国优质紫胶的发展。对苏门答腊金合欢(Acacia montana var. Sumatorana.)、光叶合欢(Albizia meyeri)、复羽叶栾树(Koelreuteria bipinnata)的放养胶虫试验结果表明,这3种树种可以作为4号胶虫的良好寄主予以利用或推广。  相似文献   
16.
Abstract

Signal molecules are among the major factors required for the legume–bacteria symbiosis. The excretion of signal molecules by plants stimulates the bacterial Nod genes resulting in the production of lipochitooligosacharides (LCOs). LCOs cause root hair deformation (RHD) and induction of nodule cells division, leading to the formation of nodules. The chemical structure of LCOs determines their biochemical activities; for example, removal of the sulfate group can significantly reduce the morphogenic activities of LCOs. Stressful conditions interrupt the excretion of signal molecules by the legumes' roots and consequently the inhibition of LCO production by the bacteria. This research has studied the effect of different concentrations of LCOs on RHD of two soybean [Glycine max (L.) Merr] cultivars, AC Bravour and Maple Glen, under acidity stress. In the first experiment, two different concentrations of LCO (10?7 and 10?6M) and in the second experiment, three different concentrations of LCO (10?7, 10?6, and 10?5M) were added to the soybean roots subjected to the pH levels of 4, 5, 6, and 7 for 24 h. By microscopy observation, the ratios of RHD were determined. Addition of LCOs resulted in RHD in both cultivars. Maple Glen roots responded similarly to different concentrations of LCO, whereas roots of AC Bravour responded differently. The concentration of 10?5M LCO could inhibit the stressful effect of pH 4 on RHD compared with pH 7 in both cultivars. The significant interaction between LCO and pH suggests that the effect of LCO on RHD may be more significant under higher levels of acidity.  相似文献   
17.
金叶含笑的育苗及栽培管理技术   总被引:2,自引:0,他引:2  
金叶含笑树干挺拔,树形丰满,枝条开张,是良好的园林风景树和绿艺树,既可作为城市道路绿化,也可作为营造园林景观配置之用,值得大力推广。文章介绍了金叶含笑育苗栽培技术,包括形态特征,生态习性,播种育苗、管理及病虫害防治等。  相似文献   
18.
In a soil lacking indigenous Bradyrhizobium japonicum , soybean ( Glycine max [L.] Merr.) nodulation depends upon the number of rhizobia applied with the inoculum. This field study reports the effect of different rates of applied rhizobia on nodulation, dry matter and nitrogen content in soybean in a Mediterranean soil lacking B. japonicum.
Treatments included six rates of B. japonicum , ranging from 2.5 × 104 to 6.075 × 106 rhizobia cells per seed applied to the seed as peat inoculant at planting, 100 kg N ha−1 and an uninoculated control. The experiment was conducted in an Entisol soil. Regression analysis showed linear relationship between the rate of applied rhizobia and the number of the nodules per plant or the dry weight per nodule. In early stages of development (32 and 68 days after planting) plant dry weight was not affected by inoculation rate. At harvest a rate of 7.5 × 104 rhizobia cells per seed was necessary for maximum total and stover dry weight. A higher rate, 6.75 × 105 rhizobia cells per seed, was required to obtain maximum grain yield, total N content in plant tops and grain N content. Grain percentage N was increased up to 2.025 × 106 rhizobia cells per seed. Nitrogen application increased grain yield, total N content and grain N content at the same level as the lower inoculation rate.  相似文献   
19.
T. J. Zhao  J. Y. Gai 《Euphytica》2006,152(3):387-396
Most of the cytoplasmic-nuclear male-sterile (CMS) lines of soybean were developed only from a limited cytoplasm sources and performed not as good as required in hybrid seed production, therefore, to explore new male-sterile cytoplasm sources should be one of the effective ways to improve the pollination and hybridization for a better pod-set in utilization of heterosis of soybeans. In the present study, total 80 crosses between 70 cultivated and annual wild soybean accessions and three maintainers (N2899, N21249, and N23998) of NJCMS1A were made for detecting potential new sources with male-sterile cytoplasm. The results showed that in addition to the crosses with N8855.1 (the cytoplasm donor parent of NJCMS1A) and its derived line NG99-893 as cytoplasm parent, there appeared three crosses, including N21566 × N21249 and N23168 × N21249, with male-sterile plants in their progenies. According to the male fertility performance of backcrosses and reciprocal crosses with the tester N21249, the landrace N21566 and annual wild soybean accession N23168 were further confirmed to have male-sterile cytoplasm. Accordingly, it was understood that the source with male-sterile cytoplasm in soybean gene pool might be not occasional. The results also showed that the genetic system of male sterility of the newly found cytoplasm source N21566 was different from the old cytoplasm source N8855.1, while N23168 was to be further studied. Based on the above results, the derived male-sterile plants from [(N21566 × N21249) F1 × N21249] BC1F1 were back-crossed with the recurrent parent N21249 for five successive times, and a new CMS line and its maintainer line, designated as NJCMS3A and NJCMS3B, respectively, were obtained. NJCMS3A had normal female fertility and stable male sterility. Its microspore abortion was mainly at middle uninucleate stage, earlier than that of NJCMS1A and NJCMS2A. The male fertility of F1s between NJCMS3A and 20 pollen parents showed that 7 accessions could restore its male fertility and other 13 could maintain its male sterility. The male sterility of NJCMS3A and its restoration were controlled by one pair of gametophyte male-sterile gene according to male fertility segregation of crosses between NJCMS3A and three restorers. The nuclear gene(s) of male sterility in NJCMS3A appeared different from the previously reported CMS lines, NJCMS1A and NJCMS2A. The development of NJCMS3A demonstrated the feasibility to discover new CMS system through choosing maintainers with suitable nuclear background.  相似文献   
20.
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