克隆植物对异质性生境的适应对策研究

植物的生境在时间和空间上都是异质性的，即使在很小的尺度上这种异质性也是存在的。克隆生长使得克隆植物在理论上更适应利用异质性环境，本文以几种克隆植物为对象，采用实验生态学方法，着重从生理生态特性、信号物质传导方面探讨克隆植物对异质性环境的适应对策。 以匍匐茎克隆植物野草莓(Fragaria vesca)为对象，研究了不同海拔梯度种群(1800m和3900m)对光照和养分资源斑块性分布生境的响应。研究结果显示：与资源的空间同质性处理(I) 和(II) 相比, 资源的空间异质性处理(III) 和(IV) 两个种群野草莓的近端、远端和整个克隆片段的生物量和分株数均获得显著增加。经历低光高养近端分株与经历高光低养的远段分株相连时，相比与低光高养的同质生境，来自两个海拔的种群分配更多的生物量到根；经历高光低养近端分株与经历低光高养远端分株相连时，相比于高光低养的同质生境，来自两个海拔的种群分配更少的生物量到根，类似的生物量分配格局在远端分株也被观察到。相比于高光低养同质性生境，当与低光高养远端分株相连时经历高光低养近端分株有更大的叶面积；相比于高光低养同质性生境，当与低光高养近端分株相连时经历高光低养远端分株有更大叶面积。实验结果表明, 资源交互斑块性生境中野草莓发生了克隆内分工。通过克隆内分工, 克隆植物能有效的利用异质性分布的资源, 缓解资源交互斑块性分布对克隆植物生长的不利影响。 以匍匐茎克隆植物蛇莓(Duchesnea indica)为对象, 研究其在高光照低水分斑块和低光照高水分斑块组成的资源交互斑块性生境中的克隆内分工。结果显示，当生长于高光照低水分(HL)条件下近端分株(basal ramets)与生长于低光照高水分(LH)条件下的远端分株(apical ramets)之间的匍匐茎连接时，近端分株根冠比显著下降，而远端分株根冠比显著增加，近端分株叶面积和远端分株总根长显著增加；当与低光照高水分条件下的远端分株相连时，近端分株叶片光合速率和叶绿素含量也相应增加。此外，克隆分株间资源交互传输显著提高蛇莓的生长表现（生物量和分株数）。因此，在光、水资源交互斑块性环境中克隆植物蛇莓分株在生物量分配、资源获取器官形态和生理特性方面发生了环境诱导的功能特化。这种对局部丰富资源的趋富特化在一定的程度上增强了克隆分株对资源的吸收利用能力，克隆内资源共享有助于缓解资源交互性斑块生境对克隆植物生长的不利影响，有效地提高克隆植物在其生境中存活与定居能力。 一个盆栽实验被采用以便调查克隆整合对经受局部沙埋的根状茎克隆植物沙生苔草(Carex praeclara)的影响，结果显示随着沙埋深度的增加，切断分株间的根状茎连接将显著降低经受沙埋处理分株的存活。当克隆植物经历局部沙埋时，切断分株间根状茎连接对其克隆生长（生物量、分株数和叶片数量）有显著负影响。耗-益(cost-benefit)分析显示，当与经历沙埋处理的远端分株相连时，近端分株的生长表现没有遭受任何负面影响。与经历沙埋处理远端分株相连时，近端分株的光合能力随沙埋深度的增加而增加。分株间的源-汇反馈调节机制所导致的补偿性反应减缓了局部沙埋对克隆植物生长的负效应。因此，克隆整合有助于提高经历局部沙埋克隆植物的存活，克隆植物在沙化地区植被恢复与重建方面具有重要意义。 克隆植物分株间的匍匐茎或根状茎连接不仅可以传输水分、矿质养分、光合产物，而且还可以传输信号物质。以根状茎克隆植物黑褐苔草(Carex alrofusca)为对象，采用盆栽实验研究外源茉莉酸诱导克隆片段相连分株间信号物质传导。结果显示，相比中龄和老龄分株，幼年分株对1mM茉莉酸诱导有显著反应。茉莉酸引起幼年分株叶片浓缩单宁含量显著增加，同时其叶片可溶性碳水化合物和氮含量降低。茉莉酸诱导后，幼年分株被昆虫咬食叶面积比率显著下降。因此匍匐茎或根状茎传也是克隆植物分株间信号物质传导重要通道，克隆植物通过分株间的风险扩散策略增强了对幼嫩植物组织器官的保护，这对克隆植物的存活或生长具有重要意义。

干旱胁迫下草莓水分调控及光合特性研究

以盆栽草莓(Fragaria×ananassa)为材料研究了水分胁迫下克隆植物草莓母株和子株间的水分调控机制及其与碳同化、光系统II激发能分配的关系。实验材料分为匍匐茎连接和剪断两个大组，进行两步实验。第一步实验，对连接组和剪断组的所有母株控水，子株充分供水；4天后进入第二步实验，把连接组分为两小组，对其中一组充分供水子株开始控水，另一组保持不变。结果表明，土壤干旱引起母株叶片失水，并使其净光合速率和气孔导度显著降低。但是连接组中供水良好的子株能有效缓解缺水母株的水分胁迫。当供水良好的子株也开始受到干旱处理的时候，则会加剧与之相连母株的水分胁迫。受胁迫母株可以通过加强渗透调节能力和降低水势从相连子株获取水分。虽然土壤干旱会造成受胁迫母株叶片脱落酸（abscisic acid, ABA）含量的大幅度增加，但是与之相连子株的叶片ABA含量并没有增加；并且气孔导度与ABA变化趋势一致。因此，我们认为：(1)草莓母株和子株间的水分运输是由二者的水势差驱动的；（2）ABA不会通过匍匐茎在母株和子株间传递并影响相邻子株气孔导度；（3）在水分异质性较大情况下，生理整合可明显提高克隆系统的碳同化能力和光系统II激发能利用效率。 同时研究了水分胁迫对草莓叶片叶绿素荧光诱导动力学参数Fm的影响。结果表明，在水分胁迫初期, 活体草莓叶片失水萎缩、叶面积和叶片厚度减小，单位叶面积的叶绿素含量升高，此时叶绿素荧光动力学参数Fm上升；当水分胁迫进一步加剧，单位叶面积的叶绿素含量开始下降，但Fm没有随之下降。离体叶片测定则没有出现Fm上升这一过程，Fm随着单位叶面积叶绿素含量的下降而下降。叶片叠加实验证明，增加叶片厚度也可以使Fm上升。综上我们认为在干旱胁迫进程中，活体草莓叶片的荧光动力学参数Fm出现上升是由单位面积叶绿素含量和叶片结构的变化共同决定的。

克隆植物东方草莓对异质生境的适应对策

克隆植物被认为比非克隆植物更宜于利用异质性环境。在复杂的空间异质环境中，克隆植物可能形成了各种有效利用环境异质性的适应对策。对于克隆植物适应机制的研究，前人已做了大量的工作，特别是从形态和生物量分配等方面对简单异质生境下克隆植物的克隆整合和克隆分工进行了详细的研究。本研究以分布广泛的克隆植物东方草莓（Fragaria orientalis）作为研究对象，应用野外调查和实验生态学方法，采用多对比度单资源模型和不同向双资源模型，从形态和生理生态的角度，研究复杂异质生境下克隆植物的整合和分工及其耗益问题，分析不同类型的生境对克隆植物整合和分工的修饰作用，进而探讨克隆植物对异质生境的适应策略。克隆构型和分株种群特征是植物克隆生长及其生态适应对策研究的基本内容。本文通过野外调查，研究在不同光照条件下东方草莓克隆构型、分株种群特征以及点分布格局。结果表明：东方草莓的克隆构型随光照发生相应的变化，低光照下其匍匐茎节间长和分枝角度均增大而分枝强度减小；随光照减弱，东方草莓分株种群的生物量、根冠比和分株种群密度显著降低；不同光照下东方草莓分株均以随机分布为主但不同尺度下有所差异，其分布格局强度依次为旷地<林缘<林下。结合克隆植物对资源的利用对策，探讨了克隆构型和分株种群特征以及分布格局随环境条件变化的生态适应意义。不同生境斑块条件下克隆植物可能采取不同的适应对策。采用盆栽实验，研究不同水分对比度下克隆整合及其生理生态特征，并对单向和交互资源中东方草莓的克隆整合做了对比研究。结果显示：高的水分对比度能够促进东方草莓的克隆整合，并能刺激相连分株增加光合作用，东方草莓体内的氧化—抗氧化系统也II随对比度做出相应的反应。耗-益分析表明胁迫分株的受益是以供给分株的损耗为代价的，但从克隆片段总体来说是受益的。单向资源中东方草莓生长的绝对值高于交互资源，但耗-益分析表明生长于交互资源下东方草莓的克隆整合获益大于生长于单向资源下东方草莓的克隆整合获益。长期生长于特定生境的克隆植物，在进化过程中其克隆整合和克隆分工在对资源异质性的适应策略方面可能有所侧重。采用盆栽实验对来自不同海拔梯度的东方草莓的克隆整合和克隆分工对异质资源的适应对策进行了研究。实验结果表明，来自高海拔的东方草莓可塑性较差。来自两个海拔的东方草莓对切断匍匐茎的表现有所差异，总体上切断匍匐茎对来自高海拔的东方草莓影响更大些。另外，来自高海拔的东方草莓表现出更高的克隆分工。IIIClonal plants are known to be more suitable for the habitats of heterogeneousresources than nonclonal plants, perhaps due to their well developed adaptivestrategies to environmental heterogeneity. Many studies have been done on theadaptive mechanisms of clonal plants, especially on the clonal integration anddivision of labor with morphology and biomass allocation under simpleheterogeneous habitats. Based on field surveys, laboratory experiments, multi-contrastunidirectional resource model and reciprocal resource model, Fragaria orientalis, aRosaceae stoloniferous herb that widely distributes in China, was used to study thisplant’s morphological and physiological responses to complicated heterogeneoushabitats in terms of its clonal integration, division of labor and cost-benefit, as well astheir modifications by different habitats, so as to better understand the adaptivestrategies of clonal plants under heterogeneous environments.Clonal architecture and ramet population characteristics are of the major concernin the studies on growth and adaptive strategies of clonal plants. Clonal architecture,ramet population characteristics and spatial point pattern of F. orientalis underdifferent light intensity were studied with field observations. The results showed that,clonal architecture changed with light availability: Internode-lengths and branchangels of stolons were larger while branch intensities were smaller under lower lightintensity than those under higher light intensity; Biomass of ramet population,root-shoot ratio and density of ramet population decreased significantly with reduce oflight intensity; Under all light intensities, spatial pattern of ramets was mainlyrandomly distributed but it changed with different scales, with pattern intensity as:open space < forest edge < understory. Adaptation significance of the clonal architecture, the ramet population characteristics and the spatial pattern changing withdifferent environments was discussed according to these results.Clonal plants may take different adaptive strategies under different patches. Withpot culture, clonal integration and physiological parameters of F. orientalis underdifferent water contrasts were studied, and clonal integration under unilateralresources and reciprocal resources were also compared. The results suggested that,high water contrast improve the clonal integration of F. orientalis and increase thephotosynthesis of connected ramets. Oxidative and antioxidative system of F.orientalis also responded with changing water contrasts. According to cost-benefitanalysis, the drought-stressed ramets obtained benefits from the connectedwell-watered ramets, and as a whole, the clonal fragment could also get benefits.Growth of F. orientalis in homogeneous resources was better than that inheterogeneous resources, but the whole plant got more benefit through clonalintegration in heterogeneous resources than in homogeneous resources.Pot culture experiments were also used to study the adaptive strategies inutilizing heterogeneous resources by the plant populations from different altitudes.The results showed that, F. orientalis from alpine zones were shorter and lessexpanded with poorer clonal plasticity than those from middle mountains. F.orientalis from two different altitudes showed different responses to stolon severing,and as a whole, stolon severing had more influence on F. orientalis from alpine zones.In addition, F. orientalis from alpine zones exhibited higher division of labor, whichsuggested that clonal plants from different habitats develop their own adaptivemechanisms in their clonal integration and division of labor in response toenvironmental heterogeneity.

Obtención de clones de alcornoque (Quercus suber L.) mediante embriogénesis somática: aplicación de medios líquidos y biorreactores en la sincronización de los procesos de desarrollo y maduración de los embriones

El alcornoque tiene un gran valor ambiental, como integrante de los ecosistemas forestales mediterráneos, e interés comercial por el valor de la bellota (alimentación del cerdo ibérico), el carbón, la madera y sobre todo por las aplicaciones industriales del corcho. Las posibilidades de mejora genética del alcornoque, como las de otras especies forestales, están limitadas por sus largos ciclos reproductivos y porque su propagación vegetativa mediante estaquillado solo es posible en estados muy juveniles. Por ello este sistema de propagación tiene muy poca, o ninguna, utilidad práctica en la mejora genética. La embriogénesis somática es la vía más apropiada para la clonación de muchas especies forestales y ha hecho posible el desarrollo a gran escala de plantaciones multivarietales de coníferas. En alcornoque es posible la regeneración completa de árboles adultos mediante embriogénesis somática. Con los protocolos actuales (en medio semisólido), los embriones se generan formando acúmulos y en la fase de multiplicación conviven embriones en distintos estados de desarrollo. Es un sistema asincrónico, con baja eficacia para la propagación en masa, que no elimina completamente las dificultades para el desarrollo de programas de mejora genética del alcornoque. En otras especies la utilización de medios líquidos ha mejorado: la sincronización, productividad de los cultivos, el manejo y reducido los costes de producción. Por ello el desarrollo de suspensiones embriogénicas de alcornoque se plantea como una vía para aumentar la eficacia de la propagación clonal a gran escala. En la presente tesis se desarrollan cultivos embriogénicos de alcornoque en medio líquido. El capítulo 3 aborda el establecimiento y mantenimiento de suspensiones, el capítulo 4 el desarrollo de una fase de proliferación en medio líquido y el capítulo 5 la utilización de sistemas de cultivo en medio líquido, estacionarios y de inmersión temporal, como vía para favorecer la maduración de los embriones somáticos. Para iniciar los cultivos en medio líquido se emplearon agregados de embriones tomados de la fase de proliferación en medio semisólido. Cuando estos agregados se inocularon directamente en medio líquido no se logró el establecimiento de las suspensiones. El establecimiento se consiguió empleando como inóculo las células y Resumen pequeños agregados embriogénicos, de tamaño comprendido entre 41 y 800 μm, desprendidas por agitación breve de los agregados de embriones. El mantenimiento se logró inoculando en baja densidad masas embriogénicas compactas de tamaño comprendido entre 0,8 y 1,2 mm. Estas suspensiones, muy heterogéneas, mantuvieron su capacidad de proliferación y de regeneración de embriones al menos durante diez subcultivos consecutivos. El protocolo de iniciación y mantenimiento, desarrollado inicialmente con un solo genotipo, fue eficaz cuando se probó sobre otros 11 genotipos de alcornoque. En la fase de proliferación se ensayaron tres tipos de envase y tres velocidades de agitación. La combinación envase × velocidad determinó el intercambio gaseoso, la disponibilidad de oxígeno y el estrés hidrodinámico. Los agregados embriogénicos de alcornoque crecieron incluso en condiciones de hipoxia no siendo la disponibilidad de oxígeno un factor limitante del crecimiento para tasas de trasferencia de oxígeno comprendidas entre 0,11 h-1 y 1,47 h-1. Por otra parte la producción de biomasa creció con el estrés hidrodinámico para valores de índice de cizalladura inferiores a 5 x 10-3 cm min-1. La mayor producción de biomasa se obtuvo con matraces Erlenmeyer de 100 ml y alta velocidad de agitación (160 rpm) mientras que la diferenciación de embriones se vio favorecida por bajas velocidades de agitación (60 rpm) asociadas con bajas disponibilidades de oxígeno. La posibilidad de madurar embriones de alcornoque en medio líquido se estudió utilizando sistemas de inmersión permanente y sistemas de inmersión temporal. En inmersión permanente no se diferenciaron embriones cotiledonares (posiblemente por hiperhidricidad). Los sistemas de inmersión temporal permitieron obtener embriones maduros en estado cotiledonar y capaces de regenerar plantas in vitro. Concentraciones de sacarosa superiores a 60 g l-1 y frecuencias de inmersión iguales o inferiores a una diaria, tuvieron efectos negativos para el desarrollo de los embriones somáticos. En los sistemas de inmersión temporal los parámetros físico-químicos del medio de cultivo se mantuvieron estables y no se observó ninguna limitación de nutrientes. No obstante, estos sistemas se vieron afectados por la evaporación que generó el flujo de aire necesario para desplazar el líquido en cada periodo de inmersión. Abstract ABSTRACT Cork oak is one of the most important tree species of the Mediterranean ecosystem. Besides its high environmental value has a great economic interest due to the sustainable production of acorns (to feed the Iberian pig) charcoal, timber and cork, which is a renewable natural product with various technological applications. As happens with other forest species, cork oak genetic improvement programs are limited by their long life cycles and because vegetative propagation by cuttings it´s only possible in very juvenile plants. Hence this propagation system is useless or has little practical use for breeding cork oak. Plant regeneration by somatic embryogenesis is the most suitable way for cloning many forest species, and it is the enabling technology which has allowed the establishment of large-scale conifer multi-varietal plantations. Clonal plant regeneration of mature cork oak trees can be achieved through somatic embryogenesis. Somatic embryos at different stages of development and forming clusters are produced during the multiplication phase with current protocols (using semisolid medium). This is an asynchronous low-efficient process not suitable for mass propagation, and therefore it does not solve the difficulties presented by cork oak breeding programs. Culture in liquid medium has been used with other species to improve: synchronization, yield, handling, and to reduce production costs. Thus the development of cork oak embryogenic suspension cultures is envisaged as a way to increase the efficiency of large scale clonal propagation. The thesis herein develops cork oak embryogenic cultures in liquid medium. In chapter 3 establishment and maintenance of suspension cultures are developed, chapter 4 studies proliferation phase in liquid medium and chapter 5 considers the use of different systems of culture in liquid medium, both stationary and temporary immersion, as a way to promote somatic embryos maturation. Clusters of embryos taken from proliferating cultures on semisolid medium were used to initiate the cultures in liquid medium. When these clusters were inoculated directly in liquid medium establishment of suspension cultures was not executed. However using, as initial inoculum, cells and cell aggregates with a size between 41 and 800 μm detached from these clusters of embryos, subjected to a brief shaking, suspension cultures could be established. Suspension maintenance was achieved by inoculating compact embryogenic Abstract clumps with a size between 0.8 and 1.2 mm at low density. The suspension cultures, very heterogeneous, retained both their proliferation and embryo regeneration capacity for at least ten consecutive subcultures. The initiation and maintenance protocol, initially developed with a single genotype, was effective when tested on 11 additional genotypes of cork oak. In proliferation phase three types of vessels and three different levels of agitation were assayed. The combination vessel × orbiting speed determined gas exchange, oxygen availability and hydrodynamic stress. Cork oak embryogenic aggregates grew even under hypoxia conditions; oxygen availability at transfer rates between 0.11 and 1.47 h-1 was not a limiting factor for growth. Furthermore the biomass production was increased with hydrodynamic stress when shear rate values were of less than 5 x 10-3 cm min-1. The highest biomass production was obtained with 100 ml Erlenmeyer flask and high stirring speed (160 rpm) while the differentiation of embryos was favored by low agitation speeds (60 rpm) associated with low oxygen availability. The possibility to mature cork oak somatic embryos in liquid medium was studied using both permanent immersion systems and temporary immersion systems. Cotyledonary embryos did not differentiate in permanent immersion conditions (probably due to hyperhydricity). Temporary immersion systems allowed obtaining mature cotyledonary embryos, which were able to regenerate plants in vitro. Sucrose concentrations above 60 g l-1 and immersion frequencies equal to or lower than one each 24 h had negative effects on somatic embryo development. Physicochemical parameters of the culture medium in temporary immersion systems were stable and showed no limitation of nutrients. However, these systems were affected by the evaporation generated by the airflow necessary to relocate the medium at each immersion period.

The Spatial Signature of Biotic Interactions of a Clonal and a Non-clonal Palmetto in a Subtropical Plant Community

Spatial analyses of plant-distribution patterns can provide inferences about intra- and interspecific biotic interactions. Yet, such analyses are rare for clonal plants because effective tools (i.e., molecular markers) needed to map naturally occurring clonal individuals have only become available recently. Clonal plants are unique in that a single genotype has a potential to spatially place new individuals (i.e., ramets) in response to intra- and interspecific biotic interactions. Laboratory and greenhouse studies suggest that some clonal plants can avoid intra-genet, inter-genet, and inter-specific competition via rootplacement patterns. An intriguing and yet to be explored question is whether a spatial signature of such multi-level biotic interactions can be detected in natural plant communities. The facultatively clonal Serenoa repens and non-clonal Sabal etonia are ecologically similar and co-dominant palmettos that sympatrically occur in the Florida peninsula. We used amplified fragment length polymorphisms (AFLPs) to identify Serenoa genets and also to assign field-unidentifiable small individuals as Sabal seedlings, Serenoa seedlings, or Serenoa vegetative sprouts. Then, we conducted univariate and bivariate multi-distance spatial analyses to examine the spatial interactions of Serenoa (n=271) and Sabal (n=137) within a 20x20 m grid at three levels, intragenet, intergenet and interspecific. We found that spatial interactions were not random at all three levels of biotic interactions. Serenoa genets appear to spatially avoid self-competition as well as intergenet competition. Furthermore, Serenoa and Sabal were spatially negatively associated with each other. However, this negative association pattern was also evident in a spatial comparison between non-clonal Serenoa and Sabal, suggesting that Serenoa genets’ spatial avoidance of Sabal through placement of new ramets is not the explanation of the interspecific-level negative spatial pattern. Our results emphasize the importance of investigating spatial signatures of biotic as well as abiotic interactions at multiple levels in understanding spatial distribution patterns of clonal plants in natural plant communities.

Tissue culture of forest trees: Clonal multiplication of Eucalyptus grandis L

Axillary shoot proliferation was obtained using explants of Eucalyptus grandis L. juvenile and mature stages on a defined medium. Murashige and Skoog medium (MS) supplemented with benzyladenine (BA), naphthalene acetic acid (NAA) and additional thiamine. Excised shoots were induced to root on a sequence of three media: (1) White's medium containing indoleacetic acid (IAA), NAA and indole butyric acid; (IBA), (2) half-strength MS medium with charcoal and (3) half-strength MS liquid medium. The two types of explants differed in rooting response, with juvenile-derived shoots giving 60% rooting and adult-derived ones only 35%. Thus, the factors limiting cloning of selected trees in vitro are determined to be those controlling rooting of shoots in E. grandis.

Clonal propagation and storage of subtropical pines in Queensland, Australia

Clonal forestry is the approach used for deployment of Pinus elliottii x P. caribaea hybrids in Queensland, Australia. Clonal forestry relies on the ability to maintain juvenility of stock plants while selections are made in field tests, so that genetic gains are not eroded by the effects of stock plant maturation. Two parallel approaches are employed in Queensland to maintain juvenility of clonal material. Firstly, the ortet and several ramets of each clone are maintained as archive hedges <20-cm height for the duration of field tests. Secondly, shoots from archive hedges are stored in tissue culture at low temperature and low irradiance to slow growth and slow maturation. Once the best clones have been identified, production hedges are derived from both archive hedges and tissue culture shoots. About 6 million rooted cuttings are produced annually, representing almost the entire planting program of Pinus in subtropical Queensland.

Production of cuttings in response to stock plant temperature in the subtropical eucalypts, Corymbia citriodora and Eucalyptus dunnii

Propagation of subtropical eucalypts is often limited by low production of rooted cuttings in winter. This study tested whether changing the temperature of Corymbia citriodora and Eucalyptus dunnii stock plants from 28/23A degrees C (day/night) to 18/13A degrees C, 23/18A degrees C or 33/28A degrees C affected the production of cuttings by stock plants, the concentrations of Ca and other nutrients in cuttings, and the subsequent percentages of cuttings that formed roots. Optimal temperatures for shoot production were 33/28A degrees C and 28/23A degrees C, with lower temperatures reducing the number of harvested cuttings. Stock plant temperature regulated production of rooted cuttings, firstly by controlling shoot production and, secondly, by affecting the ensuing rooting percentage. Shoot production was the primary factor regulating rooted cutting production by C. citriodora, but both shoot production and root production were key determinants of rooted cutting production in E. dunnii. Effects of lower stock plant temperatures on rooting were not the result of reduced Ca concentration, but consistent relationships were found between adventitious root formation and B concentration. Average rooting percentages were low (1-15% for C. citriodora and 2-22% for E. dunnii) but rooted cutting production per stock plant (e.g. 25 for C. citriodora and 52 for E. dunnii over 14 weeks at 33/28A degrees C) was sufficient to establish clonal field tests for plantation forestry.

Clonal propagation of Phyllanthus amarus: A hepatoprotector

Background: The micropropagation protocol for Phyllanthus amarus, an important medicinal herb used widely for the treatment of hepatitis in ethnomedicinal systems, was standardized with shoot tip and single node explants. Materials and Methods: The micropropagation was carried out for the hyperproducing ecotype (phyllanthin content 463.828 ppm; hypophyllanthin content: 75.469 ppm) collected from Aanaikatti, Coimbatore, and grown in mist chamber, CPMB, TNAU. For micropropagation studies, the leaves were trimmed off and the shoot tips (6 mm long) and nodal segments (single node) were used for initiation. Results: Shoot tips and single node explants gave a maximum of 6.00 and 7.00 multiple shoots per explant with Benzyl Amino Purine (BAP) (1.0mg/L mg/L). Upon subculturing, a shoot length of around 7 cm with an average of eight internodes per shoot was observed after 20 days in the elongation medium supplemented with BAP (0.2 mg/Lmg/L) and Indole Acetic Acid (IAA) (2.0 mg/L). Seven to ten adventitious roots developed when the elongated microshoots were cultured in half strength MS medium with Indole Butyric Acid (IBA) (2.0 mg/Lmg/L) and NAA (1.0 mg/L mg/L) in 15-20 days after transfer. The rooted shoots acclimatized successfully to field conditions. Conclusion: A method for successful micropropagation of the valuable medicinal plant was established which will provide a better source for continuous supply of plants for manufacturing drugs.