彩色马蹄莲的组织培养

以彩色马蹄莲芽眼为外植体,在添加不同激素配比的MS培养基上进行培养.结果表明:(1)较适宜诱导愈伤组织的激素组合是1.5 mg/L Zt+0.1 mg/L NAA、3.0 mg/L 6-BA+0.1 mg/L NAA或0.5 mg/L 2,4-D+0.1 mg/L NAA,出愈率分别为94.12%、100%和86.67%;较适宜诱导不定芽的激素组合是2.0 mg/L 6-BA+0.1 mg/L NAA,芽丛诱导率可达87.3%;芽增殖较适宜的激素组合是2.0 mg/L 6-BA+0.1 mg/L NAA或2.0 mg/L KT+1.0 mg/L NAA,而且在继代培养中,交替使用这两种激素组合,繁殖系数可达4倍以上;生根培养基以1/2 MS+0.3 mg/L NAA+0.2 mg/L IAA较为适宜,生根率达95%以上.(2)彩色马蹄莲小块茎形成的主要影响因素是培养基中的蔗糖浓度,最适宜蔗糖浓度为10%;10 mg/L多效唑和8 mg/L NAA对小块茎的形成有明显的促进作用,而分裂素则表现出较强的抑制作用.     

不同组织分离期对大圆头蛹虫草菌种性能的影响

为明确大圆头蛹虫草组织分离最佳分离时期,以大圆头蛹虫草优良母种为母本,采用组织分离法制备子代母种,以优良母种为对照,通过对不同组织分离期（35、40、45、50 d）子代母种平板培养、液体培养及栽培实验,考察不同组织分离期对子代母种培养性状及子实体形成能力的影响。结果表明,不同组织分离期大圆头蛹虫草子代母种培养性状存在较大的差异,其子实体形成能力与子代母种培养性状具有显著相关性,以组织分离期为40 d的子代母种性能表现最优,优良菌种筛选率最高（48%）,45 d次之（44%）,50 d最低（32%）。 明确大圆头蛹虫草优良菌种选育组织分离最佳时期为40 d,试验结果为大圆头蛹虫草优质菌种选育、复壮提供参考。     

Synthesis of Sphingosine Analogs with Acyclic Terpenoidal Carbon Skeleton

A simple and general synthetic method is described for erythro- and threo-forms of 2-amino-1,3-diols with an acyclic terpenoid-type side chain. ¹³C-NMR data are given for the triacetyl and N-acetyl derivatives of the synthetic erythro- and threo-2-amino-1,3-diols.     

桂枝化学成分研究北大核心CSCD

桂枝是临床常用中药,本课题组前期发现桂枝乙醇提取物具有抑制程序性细胞坏死的生理活性。为进一步阐明桂枝的化学成分和更好地开发利用桂枝药用资源,该文采用大孔吸附树脂、硅胶柱色谱、Sephadex LH-20柱层析、制备型高效液相色谱等多种方法对桂枝75%乙醇提取物进行了研究。此次报道从中得到的13个单体化合物,它们的结构经波谱数据分析及文献对照鉴定为脱落酸(1)、蚱蜢酮(2)、2,3-二羟基-1-(4-羟基-3,5-二甲氧基苯基)-1-丙酮(3)、赤型-1,2,3-三羟基苯丙烷(4)、1-苯基-1,3-丙二醇(5)、香豆素(6)、肉桂酸(7)、对羟基肉桂酸(8)、邻羟基肉桂酸(9)、邻甲氧基肉桂酸(10)、肉桂醛(11)、阿魏酸(12)、咖啡酸乙酯(13)。其中1-5、12和13为首次从桂枝中分离得到。     

冬虫夏草菌丝状菌源增殖培养的研究

冬虫夏草菌是珍稀濒危名贵中药材冬虫夏草的无性型菌种,是侵染蝠蛾幼虫的唯一菌种,其侵染后形成名贵中药材冬虫夏草。冬虫夏草菌在不同营养及条件下生长形态不同,主要有丝状体和菌球体两种生长形态。冬虫夏草菌丝状菌体能够侵染蝠蛾幼虫,有可能作为一种新的接种体被广泛应用;但丝状菌体对营养要求苛刻、生长缓慢、菌丝体得率低的特点,阻碍了冬虫夏草菌丝状菌体作为侵染蝠蛾幼虫的接种体的开发及应用,从而阻碍了冬虫夏草人工培殖产业化的进程。为了提高冬虫夏草菌丝状菌体的生物表达量,本文对营养及培养条件进行了优化研究,得出了最佳条件为:葡萄糖质量浓度40 g/L、酵母粉质量浓度65 g/L、培养温度17℃、MgSO_4质量浓度3 g/L、KH_2PO_4质量浓度1.5 g/L、培养时间12 d,按最优培养条件,冬虫夏草菌丝状菌体干重得率15.67 g/L,为下一步新的接种体的制备提供菌源保障。     

Circulating tumor microemboli: Progress in molecular understanding and enrichment technologies

Circulating tumor cells (CTCs) and their clusters, also known as circulating tumor microemboli (CTM), have emerged as valuable tool that can provide mechanistic insights into the tumor heterogeneity, clonal evolution, and stochastic events within the metastatic cascade. However, recent investigations have hinted that CTM may not be mere aggregates of tumor cells but cells comprising CTM exhibit distinct phenotypic and molecular characteristics in comparison to single CTCs. Moreover, in many cases CTM demonstrated higher metastatic potential and resistance to apoptosis as compared to their single cell counterparts. Thus, their evaluation and enumeration may provide a new dimension to our understanding of cancer biology and metastatic cancer spread as well as offer novel theranostic biomarkers. Most of the existing technologies for isolation of hematogenous tumor cells largely favor single CTCs, hence there is a need to devise new approaches, or re-configure the existing ones, for specific and efficient CTM isolation. Here we review existing knowledge and insights on CTM biology. Furthermore, a critical commentary on current and emerging trends in CTM enrichment and characterization along with recently developed ex-vivo CTC expansion methodologies is presented with the aim to facilitate researchers to identify further avenues of research and development.     

Arginine bi-directional translocation and breakdown into ornithine along the arbuscular mycorrhizal mycelium

Bi-directional translocation and degradation of Arginine (Arg) along the arbuscular mycorrhizal (AM) fungal mycelium were testified through ¹⁵N and/or ¹³C isotopic labeling. In vitro mycorrhizas of Glomus intraradices and Ri T-DNA-transformed carrot roots were grown in dual compartment Petri dishes. [¹⁵N- and/or¹³C]Arg was supplied to either the fungal compartment or the mycorrhizal compartment or separate dishes containing the uncolonized roots. The levels and labeling of free amino acids (AAs) in the mycorrhizal roots and in the extraradical mycelia(ERM) were measured by gas chromatography/mass spectrometry (GC-MS) and high-performance liquid chromatography (HPLC). The ERM of AM fungi exposed in either NH₄ ⁺ or urea as sole external nitrogen source had much higher ¹⁵N enrichment of Arg, compared with those in nitrate or exogenous Arg; however, glycerol supplied as an external carbon source to the ERM had no significant effect on the level of Arg in the ERM. Meanwhile, Arg biosynthesized in the ERM could be translocated intact to the mycorrhizal roots and thereby the level of Arg in the mycorrhizal roots increased to about 20% after culture of ERM in 4 mmol/L NH₄ ⁺ for 6 weeks. Also Arg was found to be bi-directionally transported along the AM fungal mycelium through [U-¹³C]Arg labeling either in the mycorrhizal compartment or in the fungal compartment. Once Arg was translocated to the potential N-limited sites, it would be further degraded into ornithine (Orn) and urea since either [U-¹³C] or [U-¹⁵N/U-¹³C]Orn was apparently shown up in the mycorrhizal root tissues when [U-¹³C] or [U-¹⁵N/U-¹³C]Arg was labeled in the fungal compartment, respectively. Evidently Orn formation indicated the ongoing activities of Arg translocation and degradation through the urea cycle in AM fungal mycelium. Supported by Science and Technology Department of Zhejiang Province (Grant No. 2006C22009).     

樟叶越桔组培苗生根和移栽技术研究

为解决樟叶越桔(Vaccinium dunalianum)组培苗生根质量不佳、移栽成活率低的问题,该研究以樟叶越桔继代苗为材料,采用单因子试验从激素类型及浓度、培养基类型和蔗糖质量浓度对其生根的适宜条件进行筛选,进一步研究了不同基质配比对樟叶越桔移栽苗存活率的影响。结果表明:激素类型和浓度、培养基类型对樟叶越桔生根率的影响最大,其次为蔗糖质量浓度;最适合樟叶越桔生根的激素及浓度为IBA2.0 mg·L~(-1)、基本培养基类型为1/4MS、蔗糖质量浓度为15 g·L~(-1),樟叶越桔组培苗最佳生根培养基为1/4MS+IBA 2.0 mg·L~(-1)+活性炭0.1 g·L~(-1)+蔗糖15 g·L~(-1),生根率达100%,平均生根数为每株7.67条;根系呈辐射状、基部无愈伤组织,组培苗生长健壮、叶色浓绿;樟叶越桔组培苗移栽时以全腐殖土基质为佳,成活率为83.7%,植株叶片舒展,生长状况良好。该研究建立的优化体系有效地提高了樟叶越桔组培生根苗的生根率和生根质量,解决了后期移栽成活困难的问题,为优良的樟叶越桔植株规模化生产提供了科学依据和技术支持。     

文心兰原球茎液体增殖培养研究

以茎尖诱导形成的原球茎(protocorm-like bodies,PLBs)为外殖体,采用液体培养方式比较了不同浓度的激素配比、蔗糖浓度和添加不同量的新鲜椰汁对文心兰PLBs增殖的影响,并比较了相同培养基成分时液体培养PLBs增殖、分化成苗和固体培养PLBs增殖和分化成苗的差异。试验结果表明:不同浓度的外源激素及其配比对文心兰PLBs增殖生长影响较大,6-BA0.5 mg/L Ad 0.05 mg/L NAA0.05 mg/L的激素组合比较适合文心兰PLBs增殖;蔗糖浓度对文心兰PLBs增殖的影响也较大,适合文心兰PLB在液体培养条件下增殖的蔗糖浓度为7.5 g/L;添加5%新鲜椰汁不仅对文心兰PLBs增殖有促进作用,而且能改善PLBs的质量;适合文心兰PLBs增殖的培养基为MS 6-BA0.5 mg/L Ad 0.05 mg/L NAA0.05 mg/L 5%椰汁 蔗糖7.5 g/L。文心兰PLBs在5周内的增殖生长曲线呈倒"V"字形,第3周的增殖速度达最高峰,而固体培养基PLBs增殖速度较慢,生长曲线几乎成直线。液体增殖的PLBs分化成苗较固体培养增殖的PLBs差。     

氧化亚铁硫杆菌的分离及其培养条件优化

目的:获得可应用于烟气脱硫的菌株,并对其培养条件进行优化.方法:从化工厂取土样分离氧化亚铁硫杆菌,分析分离菌株的形态学特征、培养特征及16S rDNA序列,确定菌株的分类地位.通过单因子实验,对培养基中主要成分硫酸亚铁和硫酸铵的浓度进行优化.利用SAS软件中的Box-Behnken法设计实验,通过响应面分析对初始pH、温度、接种量、装液量4个因素进行优化.结果:获得菌株N16,经鉴定为嗜酸性氧化亚铁硫杆菌(Acidithiobacillus ferrooxidans).确定FeSO_4·7H_2O和(NH_4)_2SO_4的最适添加量分别为60/L和1g/L.确定菌株最适培养条件为:初始pH 1.8,温度28℃,转速150r/min,接种量15%,装液量30mL.在最适培养墓及培养条件下,菌株N16的亚铁氧化率可达99.78%.结论:分离得到的菌株适合于微生物法烟气脱硫的应用.