Simple Protocol for the Micropropagation of Teak(Tectona grandis Linn.)in Semi-Solid and Liquid Media in RITA^(█) Bioreactors and ex Vitro Rooting

In Latin America the forestry of exotic species such as teak has been increasing in recent decades, due to their advantages in wood quality, rapid growth;and the relative ease of producing clones and their multiplication with respect to native species. Therefore, there is great interest in developing larger-scale propagation strategies that reduce costs and intensive manual labor. Culture in liquid media with temporary immersion and the semi-automation of the system has raised expectations for large-scale micropropagation. We report a protocol for teak, which reuses the primary explants in several culture cycles in semi-solid medium to produce nodal explants for the multiplication phase in temporary immersion bioreactors (RITA®). The control of factors such as cytokinin concentration, explants density, immersion frequencies and culture duration was analyzed. The number of shoots increased with 0.5 mg·l-1 of BA (6-Benzyladenine), alone or in combination with 0.5 mg·l-1 of Kinetin, with 2 daily immersions of 1 minute each;however, these shoots showed a high degree of hyperhydricity. When 0.05 mg·l-1 of BA was used with 1 immersion of 1 minute every 2 days, the hyperhydricity decreased. Although the number of shoots was lower, they showed good length to be used during multiplication and rooting ex vitro. Our results suggest that teak micropropagation can be simplified in two phases in vitro, the establishment and multiplication;followed by rooting ex vitro and acclimatization. This would imply a reduction in production costs, since most of the multiplication would take place in RITA®containers.

Acclimatization of <i>in Vitro</i>Propagated Pineapple (<i>Ananas comosuss</i>(L.), var. Smooth cayenne) Plantlets to <i>ex Vitro</i>Condition in Ethiopia

Pineapple (Ananas comosuss, var. Smooth cayenne), which is a popular tropical fruit, is propagated vegetatively. Conventional propagation alone does not provide clean and adequate planting material demanded in Ethiopia. Recently, in vitro multiplication has become a promising technique for large-scale production. However, the acclimatization to the external environment procedure impedes the efficiency, which needs carefully optimized acclimatization techniques. We report optimized acclimatization procedures following first- and second-stage hardening methods for in vitro pineapple plantlets. Primarily, Jiffy-7 peat pellet allowed growing plants vigorously and provided above 8% survival rate over soil mix. Nevertheless, in Ethiopia, soil mix is cheaper and locally accessible. The primarily acclimatized plantlets are needed to be hardened further for better establishment and survival in the field. Black polybag and polysleeve pots filled with soil mix were evaluated in the greenhouse. A significant difference was obtained between pots for number of roots and substrate weight. Polybags had higher root number than polysleeves and saved about 27% of substrates per plant, which is a reduction of 25% of total transportation cost. Hence, the soil mix and polybags were found to be preferable over substrates and pots, for subsequent in vitro pineapple acclimatization.

High Light Intensity Increases the CAM Expression in “MD-2” Micro-Propagated Pineapple Plants at the End of the Acclimatization Stage

This work describes the evaluation of morpho-physiological and biochemical changes in “MD-2” micro-propagated pineapple plants (Ananas comosus (L.) Merr.) grown after 30 days under low light intensity (LL, greenhouse light conditions at 250 μmol·m-2·s-1) or high light intensity (HL, field light conditions at 800 μmol·m-2·s-1). Gas exchange, leaf pH, protein content and superoxide dismutase activity (SOD) (EC 1.15.1.1) were measured every 3 h during one day. Chlorophylls content and succulence index (SI) were determined at 9 h. Results showed significant differences in CO2 exchange rates, with a maximum occurring at 6 h (3.00 and 8.25 μmol CO2 m-2·s-1 for leaves under LL and HL conditions respectively). Plants under HL conditions had higher CO2 uptake and lower pH values between 0 h and 6 h respective to LL plants. The maximum pH value was attained 3 h before in HL plants. Leaf SI was increased and chlorophyll content decreased by HL conditions. SOD activity was higher in plants under HL conditions, near doubling those of LL plants at 18 h (2.8 versus 1.5 U·mg-1 Protein respectively). Both groups showed a typical CAM phenotype, but it was stronger in HL conditions, which may confer these plants with a better acclimation to transfer to the field.

基于雷达图分析法的白鹤芋组培苗水培瓶外生根营养液浓度的筛选

为筛选白鹤芋瓶外生根的适宜营养液浓度,该研究将组培白鹤芋增殖苗栽植于含不同强度的MS液体培养基(1/4 MS、1/2 MS、3/4 MS和MS)的水培系统中进行瓶外生根,通过调查生根苗的地上部和地下部形态和生理指标,并结合雷达图分析法确定最佳营养液浓度。结果表明:白鹤芋根长及叶长在1/4 MS处理中明显增加,苗总鲜重和总干重、叶绿素含量(SPAD)在1/2 MS处理中达到最大,而生根数最多的处理组为3/4 MS。雷达图分析结果显示综合得分排序为1/2 MS>1/4 MS>3/4 MS>MS,因此,确定1/2MS营养液最适于与白鹤芋水培瓶外生根。

佛手瓜茎段组培快繁技术研究

为建立佛手瓜完整的组培快繁体系,以佛手瓜茎段为外植体,探究外植体的最佳消毒条件;以筛选的MS为基本培养基,添加3%的蔗糖和0.7%的琼脂,探究不同的激素配比对腋芽诱导、不定芽增殖和生根培养的影响。结果表明,佛手瓜茎段最佳消毒条件为75%酒精20 s+0.1%氯化汞8 min;腋芽诱导适宜培养基为MS+1.0 g·L^(-1)AC+1.0 mg·L^(-1)6-BA+0.1 mg·L^(-1)NAA和MS+1.0 g·L^(-1)AC+1.0 mg·L^(-1)6-BA+0.1 mg·L^(-1)IAA,最佳增殖培养基为MS+1.0 mg·L^(-1)6-BA+0.1 mg·L^(-1)NAA,平均增殖系数达4.01,最佳生根培养基为1/2MS+0.2 mg·L^(-1)NAA,生根率为93.33%,最适的瓶外扦插生根条件为0.5 mg·L^(-1)NAA浸泡处理30 min。研究建立的佛手瓜组培快繁体系,为优质佛手瓜种质资源的保存提供了技术参考。

肝素涂层插管生物相容性评价

对肝素涂层插管和未涂层插管设计了抗凝血、血栓形成观察以及溶血、细胞毒性、炎性和免疫反应等多种试验,从多角度综合对肝素涂层插管材料进行生物相容性评价。通过活化部分凝血活酶时间(APTT)、凝血酶原时间(PT)、纤维蛋白原降解产物(FIB)、凝血酶时间(TT)、血小板活化因子、纤维蛋白吸附等试验,测定样品的体外抗凝血性,然后通过半体内血栓形成试验,模拟插管在动物体内的使用环境和过程,观察样品引起血栓形成的状况。同时,通过溶血试验和细胞毒性试验以及炎症反应、补体激活、免疫球蛋白等检测,进一步对样品进行血液相容性评价。结果显示,肝素涂层实验组APTT和TT得到有效延长,而其他体外抗凝指标未见显著变化;在动物半体内模型试验和检测中,肝素涂层实验组6 h血栓形成的各项指标均低于未涂层对照组,表明肝素涂层通过抑制内源性凝血途径达到了预期的抗凝效果;而溶血率、细胞毒性、炎症反应、补体激活、免疫球蛋白等方面的试验结果与未涂层对照组无差异,表明肝素涂层对材料的血液相容性无不良影响。结果表明,肝素涂层显著提高了动静脉插管的体内外抗凝血性,具有良好的生物相容性,可提高临床应用的安全性。

石榴组培苗试管外生根条件探究

目的:筛选石榴组培苗试管外生根的最适条件,为石榴工厂化育苗奠定理论基础。方法:以‘白花玉石籽’石榴组培苗为试验材料,研究不同因素对石榴组培苗试管外生根的影响,筛选最适试管外生根条件。结果:最适石榴试管外生根条件培养石榴组培苗生根率及移栽成活率均达到100%,且比试管内生根培养节约了30 d的时间,移栽成活率提高了14.79%。结论:培养15 d的石榴组培苗移栽到基质(草炭∶蛭石=1∶4)中,用WPM+0.8 mg/L IBA浇透基质,覆膜12 d,在温度25℃、光照强度2000 lx、光照10 h条件下培养,提高了石榴组培苗的生根率及移栽成活率。

风箱果组织培养不定芽的试管外生根及植株再生

以风箱果幼苗顶芽为外植体,诱导不定芽,通过试管外生根技术建立植株再生体系。结果表明：以MS+BA1．0 mg·L^(-1)+NAA1．0 mg·L^(-1)为诱导培养基,MS+BA0．8 mg·L^(-1)+NAA0．4 mg·L^(-1)为增殖培养基,MS+IBA0．5 mg·L^(-1)+GA_30．3 mg·L^(-1)为壮苗伸长培养基,效果较好；试管外生根以100 mg·L^(-1)NAA处理30 min效果最佳,生根成活率为93．1%。

澳洲茶树组培继代芽瓶外生根技术研究

以培养40d的澳洲茶树组培继代芽为试验材料,研究不同基质、生长调节剂及处理方式和扦插时间对其瓶外生根效果的影响。结果表明,澳洲茶树瓶外生根的最佳方案是,在冬季,以红心土作为基质,将≥3cm的继代芽浸泡于0.4mg/m L的ABT溶液中30-50min,并蘸取相应浓度激素溶液与滑石粉的混合匀浆后扦插。此方案的生根率为92%,生根8.96条,平均根系长2.4cm,对促进澳洲茶树繁殖效率,降低生产成本具有重要意义。

甘蔗试管苗瓶外生根技术的研究

为优化甘蔗试管苗瓶外生根的环境条件,提高成活率,降低生产成本,进行了外界环境因素对甘蔗无根试管苗瓶外生根及生长的影响研究。结果表明,高肥力基质(如商品基质)处理的无根试管苗成活率低,但成活植株生长快,植株高;而低肥力基质(如新鲜河沙土)有利于无根试管苗生根成活,但植株生长慢;适合甘蔗无根试管苗移栽的基质包括新鲜河沙土、田园土和河沙与田园土的混合物。温度、光照和湿度是甘蔗试管苗瓶外生根维持高存活率的关键外部因素,利用遮阳网和盖膜等措施调节温度、湿度和光照可使试管苗的生长环境逐渐过渡到自然环境条件。试管苗瓶外生根技术有利于简化传统甘蔗试管苗生产,降低生产成本,促进甘蔗健康种苗的推广应用。

马大杂种相思瓶内和瓶外生根技术研究

以增殖培养的马大杂种相思无菌苗为材料，进行瓶内生根（采用增殖培养30d，2～3cm的无菌苗）和瓶外生根（采用增殖培养45d，3～5cm的无菌苗）技术的研究，并对2种生根技术进行了经济效益的简单比较分析。结果表明：将增殖培养30d的马大杂种相思无菌苗接入1／2MS＋IBA 1．0mg·L^-1＋NAA 0．5mg·L^-1＋蔗糖30％的培养基中，生根率可达99．43％，15d后移栽，存活率达98．0％；而将增殖培养45d的马大杂种相思无菌苗用100mg·L^-1的IBA溶液浸泡1h进行瓶外生根实验，生根率可达94．67％。按生产10000株苗计算，瓶外生根的经济效益比瓶内生根的多1288．26元，效益比较可观，瓶外生根技术可以应用于马大杂种相思组培苗的大量生产。

黑木相思组培苗瓶外生根技术研究

以黑木相思优良无性系组培苗为材料,开展了移栽基质与基质含水率,生根促进剂种类、浓度和处理时间,光照强度和光周期对组培苗瓶外扦插生根影响的研究,探讨组培苗瓶外生根的最佳条件,以期为黑木相思快速繁殖技术提供一定理论支撑和技术支持。结果表明:移栽基质以泥炭土+蛭石+珍珠岩(5∶4∶1)效果最好,其平均生根率达94.45%;含水率以50%效果最佳;生根促进剂以ABT(50 mg·L^(-1)处理25 min)表现最好,其平均生根数、平均根长、平均生根率分别为11.05条、1.67 cm、98.66%;光照强度对黑木相思组培苗瓶外生根影响显著,在光照强度为45～135μmol·m^(-2)·s^(-1)内,随着光照强度的增加,平均生根数与平均生根率随之增加,而平均根长呈下降趋势;光周期对黑木相思组培苗瓶外生根的影响不显著。

外源激素处理对甘蔗试管苗瓶外生根的影响

[目的]探讨甘蔗试管苗瓶外生根的条件,以期为其瓶外生根技术的开发和应用提供理论依据。[方法]以处于增殖培养阶段的甘蔗(新台糖22号)无根试管苗为试验材料,研究了3种不同的外源激素及不同浓度激素处理对该试管苗瓶外生根的影响。[结果]一定浓度的赤霉素处理,对新台糖22号无根试管苗基部节的生长有明显的促进作用,并且可以显著提高其移栽存活率,可达到对照组的2.2倍以上,其中以1.5 mg/L赤霉素处理组试管苗的存活率最高,达到83.33%。移栽前用生根粉或萘乙酸浸泡新台糖22号试管苗基部,对试管苗的移栽成活率及其以后的植株生长没有显著影响。[结论]该研究结果为甘蔗试管苗瓶外生根技术的应用提供了科学依据。

栝楼组织培养及非试管苗快繁技术研究

对栝楼茎尖组织培养的研究结果表明,不同激素浓度对其芽丛的形成、分化及根的形成有不同的影响,栝楼茎尖组织培养的最佳诱导、增殖和生根培养基分别是MS+6-BA1.5mg/L+IBA0.3mg/L+NAA0.05mg/L、MS+6-BA1.0mg/L+IBA0.3mg/L+NAA0.05mg/L和1/2MS+IBA0.5mg/L。利用栝楼组培苗在隔离网棚中抽出的匍匐茎进行非试管快繁育苗,可低成本、快速繁育出栝楼优质种苗,其中以9-10月份繁出的种苗在当年假植中形成的地下块茎最大,定植当年坐果率、经济产量最高。

优质魔芋组培苗瓶外生根的研究

经NAA和不同浓度水平的IBA处理后,能有效促进魔芋组培苗的生根。用浓度为10mg/L的IBA处理花魔芋无根组培苗30min的效果最好,平均生根率达90.83%,平均根数也最多(达3.92条)。用花魔芋和白魔芋无根组培苗在100mg/L的NAA中速蘸后也能较好地促进生根,白魔芋的平均生根率及平均根数分别为77.54%和2.43条/株,花魔芋的分别为84.14%和1.65条/株。

轮生冬青组培苗微枝试管外生根技术

为解决轮生冬青组培工厂化育苗生根的难题,以轮生冬青组培苗为材料,采用L9(34)正交试验,探究生长调节剂种类、质量浓度与处理时间及基质类型对组培苗微枝试管外生根的影响。正交试验方差分析结果表明:生长调节剂种类对其生根率、生根数以及根系活力影响最大,基质对最长根长影响最大。隶属函数法分析结果表明:影响组培苗生根效果各因素由大到小的顺序为生长调节剂种类、基质类型、生长调节剂的处理时间和质量浓度。综合来看,轮生冬青组培苗微枝试管外生根的最理想处理组合是A2B1C3D1,即选用质量浓度为500 mg·L^-1的IBA溶液,30 min浸泡处理,基质选用草炭。

罗汉果试管苗瓶外生根研究

以罗汉果试管苗为材料,采用非试管快繁智能化育苗大棚进行了瓶内和瓶外生根移栽试验。结果表明,基部不带愈伤组织的试管苗瓶外生根处理后,生根率、最长根长、生根数分别为96.11%、4.53 cm、3.6条,最长根长显著高于瓶内生根处理,而生根率和生根数两者差异不显著;瓶内生根苗移栽成活率显著高于瓶外生根苗。通过缩短瓶外生根时间,增施叶面肥等措施,可获得较高的移栽成活率。由此证明了采用试管苗瓶外生根技术可大大提高罗汉果试管苗的生根质量。

南高丛蓝莓快繁技术体系研究

以南高丛蓝莓试管无菌丛生芽为材料,对南高丛蓝莓丛生芽的诱导与增殖、继代次数对丛生芽诱导增殖的影响、瓶内生根、瓶外生根、不同生根方式试管苗移栽成活率的大小进行了研究。南高丛蓝莓丛生芽诱导与增殖培养基以WPM+ZT 2.0 mg·L-1较佳,增殖倍数可达3.50;继代6次丛生芽增殖倍数可达24.00;瓶内生根生根培养基以WPM+ZT 0.5 mg·L-1+IBA 0.1 mg·L-1为佳,生根率可达80.73%±3.17%,生根周期为100 d;试管芽用25 mg·L-1IBA溶液浸蘸10 s,以1/6 WPM为营养液加珍珠岩作基质,生根率可达到80.00%±5.00%,生根周期为40 d;瓶外生根试管苗移栽成活率是瓶内生根试管苗的2倍。基本建立了南高丛蓝莓的试管快繁技术体系,为南高丛蓝莓的工业化育苗奠定了技术基础。

甘蔗试管苗瓶外生根技术的研究

[目的]优化甘蔗试管苗瓶外生根的环境条件,提高成活率,降低生产成本。[方法]研究外界环境因素对甘蔗无根试管苗瓶外生根及生长的影响,比较瓶内和瓶外生根试管苗的成活率及株高差异。[结果]高肥力基质(如商品基质)处理的无根试管苗成活率低,但成活植株生长快,植株高,而低肥力基质(如新鲜河沙)更有利于无根试管苗生根成活,但植株生长慢;利用遮阳网和盖膜等措施调节温度、湿度和光照可使试管苗的生长环境逐渐过渡到自然环境条件;另外,瓶内生根试管苗的成活率和株高均显著高于瓶外生根试管苗。[结论]试管苗瓶外生根技术的研究成功有利于简化传统甘蔗试管苗生根技术,降低生产成本,促进甘蔗健康种苗的大面积推广种植。

新西伯利亚银白杨微枝试管外生根与微环境因子的关系

[目的]提高新西伯利亚银白杨试管外生根的驯化效率。[方法]以新西伯利亚银白杨的无性系组培微枝为材料,通过对比试验研究了微环境因子与其试管外生根率和根系质量的相关关系。[结果]基质25%草炭+30%蛭石+45%珍珠岩的微枝生根效果最好,其隶属函数值、生根率、生根数、根长和偏根率分别为0.857、90%、11.6条/株、2.25cm和11%。用IBA处理的微枝生根效果最好,300mg/LIBA处理的隶属函数值、生根率、平均生根数、平均根长和偏根率分别为0.785、93.33%、6.12条/株、1.15cm和13.67%。20℃下微枝的生根效果最好,其隶属函数值、生根率、生根数、根长和偏根率分别为0.820、100.00%、7.80条/株、1.17cm和15.33%。75μmol/(m2.s)光照强度处理的微枝生根效果最好,其隶属函数值、生根率、生根数、根长和偏根率分别为0.686、100.00%、8.76条/株、2.08cm和38.00%。基质含水率为50%的微枝生根效果最好,其隶属函数值、生根率、生根数、根长和偏根率分别为0.894、100.00%、7.73条/株、1.75cm和13.33%。[结论]该研究为建立新西伯利亚银白杨的快速有效微繁技术体系奠定了基础。