Genetic fidelity of long-term micropropagated shoot cultures of vanilla (Vanilla planifolia Andrews) as assessed by molecular markers

Occurrence of genetic variants during micropropagation is occasionally encountered when the cultures are maintained in vitro for long period. Therefore, the micropropagated multiple shoots of Vanilla planifolia Andrews developed from axillary bud explants established 10 years ago were used to determine somaclonal variation using random amplified polymorphic DNA (RAPD) and intersimple sequence repeats markers (ISSR). One thousand micro-plants were established in soil of which 95 plantlets (consisting of four phenotypes) along with the mother plant were subjected to genetic analyses using RAPD and ISSR markers. Out of the 45 RAPD and 20 ISSR primers screened, 30 RAPD and 7 ISSR primers showed 317 clear, distinct and reproducible band classes resulting in a total of 30 115 bands. However, no difference was observed in banding patterns of any of the samples for a particular primer, indicating the absence of variation among the micropropagated plants. Our results allow us to conclude that the micropropagation protocol that we have used for in vitro proliferation of vanilla plantlets for the last 10 years might be applicable for the production of clonal plants over a considerable period of time.     

Effect of anti-ethylene compounds on isoenzyme patterns and genome stability during long term culture of <Emphasis Type="Italic">Moringa oleifera</Emphasis>

Multiplication of Moringa oleifera shoots on MS medium supplemented with 2.5 µM BAP for 3 weeks resulted in shoot vitrification which led to chlorosis, retardation of shoot formation, reduction in shoot length, necrosis of shoot tips and formation of friable calli on the base of cultured explants. Vitrification symptoms decreased when MS medium containing 2.5 µM BAP in combination with 10 µM AgNO₃, 50 µM salicylic acid (SA) or 200 µM CoCl₂ was used. Studying isoenzyme patterns of SOD, POX, CAT, GOT and EST indicated that moringa shoots multiplied without obvious variation in isoenzyme patterns up to 7 subcultures. Moringa shoots subjected to 14 subcultures and anti-ethylene compounds showed variation in isoenzyme patterns and were associated with the disappearance of vitrification which facilitated root formation and acclimatization. Under long term cultures, RAPD, ISSR and SSR indicated that AgNO₃ was the optimal anti-ethylene substance for avoidance of vitrification in moringa but it resulted in high somaclonal variation. Application of SA decreased vitrification as well as somaclonal variation compared to CoCl₂ under long term culture. Consequently, SA was recommended for moringa clonal multiplication.     

In vitro multiplication and genetic stability of two species of <Emphasis Type="Italic">Micranthocereus</Emphasis> Backeb. (Cactaceae) endemic to Bahia,Brazil

The two targeted species of this study, Micranthocereus flaviflorus subsp. densiflorus and M. polyanthus subsp. alvinii, are endemic to the state of Bahia and have ornamental value. The main goal of this work was to micropropagate these species and to evaluate the genetic stability of the regenerated plants. To do so, shoots originated from in vitro germinated plants were inoculated in MS/2 (Murashige, Skoog, Physiol Plant 15:473–497, 1962) media containing 1.34 μmol L^?1 of α-naphthaleneacetic acid (NAA) for morphogenesis induction. This was repeated for three consecutive subcultures, and the subcultured shoots were designated by order of production as S1, S2 and S3. Retention of morphogenic potential and acceleration of organogenic response was observed after the three subsequent propagation events, so that if shoots were used as explant source the in vitro propagation of M. flaviflorus could be achieved in 90 days and that of M. polyanthus could be optimized to 60 days of duration. In order to perform genetic stability analysis along subcultures, ISSR markers were used and genetic variation between shoots of each subculture and their donor plant was measured with Jaccard’s similarity coefficient. This analysis revealed high genetic stability in the in vitro propagation of all the donor plants of M. flaviflorus and M. polyanthus in regards to three consecutive shoot subcultures, in which similarities were 100% for both species. The study of a greater number of subcultures is suggested to assess morphogenesis potential and genetic fidelity in long term.     

Temporary immersion bioreactors (TIB) provide a versatile,cost-effective and reproducible in vitro analysis of the response of pineapple shoots to salinity and drought

Effects of salinity (NaCl) and the carbon source mannitol (0–200 mM) on micropropagation of pineapple cv. MD2 were analyzed in temporary immersion bioreactors (TIBs). Shoot multiplication rate, shoot cluster fresh weight and levels of aldehydes, chlorophylls, carotenoids and phenolics were determined in the plant material. The content of soluble phenolics in the culture medium was also evaluated. NaCl or mannitol above concentrations of 50 mM decreased pineapple shoot multiplication and fresh weight significantly. Two hundred mM NaCl decreased multiplication rate by 71.5% and cluster fresh weight by 40.0%. NaCl increased 2.4 times the levels of other aldehydes; 1.4 times the soluble phenolics in shoots; and 1.4 times the phenolics excreted to the culture medium. On the other hand, mannitol decreased the multiplication rate and cluster fresh weight by about 60%. Mannitol increased the contents of chlorophyll b 1.4 times and soluble phenolics 2.1 times. Results indicated that pineapple cv. MD2 is more sensitive to NaCl than to mannitol. Multiplication rates indicate that a 50% reduction was obtained with 37.4 mM NaCl and 66.5 mM mannitol. These concentrations can be used to stress shoots during micropropagation in TIBs and screen for/detect somaclonal variants with an increased salinity or drought tolerance.     

Assessment of Genetic Stability in Three Generations of In Vitro Propagated <Emphasis Type="Italic">Jatropha curcas</Emphasis> L. Plantlets Using ISSR Markers

Tissue culture has been widely employed in Jatropha curcas L. for the clonal multiplication of superior genotypes. However, the evaluation of genetic stability is necessary to detect somaclonal variants. In this context, the present aim was to evaluate the genetic stability of J. curcas plantlets, obtained via indirect organogenesis, by means of ISSR markers. To supply the explant sources for in vitro propagation, the first generation of plants was produced from in vitro germination of J. curcas seeds. Fragments of cotyledonary leaves were inoculated into medium supplemented with 1.5 mg L^?1 BAP and 0.05 mg L^?1 of IBA for induction of callogenesis. The resulting calli were transferred to bud induction medium. Subsequently, the buds were cultured in medium for elongation, giving rise to the second generation of plants. These plants provided new buds, which were excised and subcultured in elongation medium, yielding a third generation of plants. To evaluate genetic stability in three plant generations, twelve ISSR primers were used, resulting in 124 bands showing 41.93 % of polymorphism. Increase was observed in the level of somaclonal variation (SV) over the generations. The present study reports, for the first time, the analysis of genetic stability in J. curcas plantlets regenerated via indirect organogenesis by means of ISSR markers. The results suggest that the indirect route is associated to higher levels of genetic instability, which also increased with successive subcultures. The ISSR markers were efficient in detecting SV, and the generated genetic variability may be useful for breeding programs.     

Evaluation of clonal integrity in desert date tree (Balanites aegyptiaca Del.) by inter-simple sequence repeat marker assay

Axillary shoot bud multiplication as a safest mode of micropropagation to obtain clonal progeny was revealed through the application of molecular marker technique in Balanites aegyptiaca. Inter-simple sequence repeat (ISSR) markers were used to evaluate the genetic constancy of micropropagated plantlets chosen from a clonal collection of shoots that originated from mature nodal explants (mother plant). Out of 20 ISSR primers screened, ten primers yielded reliable and reproducible patterns of amplified products in all the tested plants. In this study, on an average, 11.7 bands were amplified per primer. A total of 117 bands were scored for the tissue culture-raised plantlets; 115 amplification products were monomorphic and 2 bands were polymorphic. Based on the ISSR band data, 98.2 % genetic uniformity was detected among the regenerants. Thus, the amplification products validated that the plantlets were true-to-type in morphological or growth characteristics when compared with the mother plant.     

Genetic fidelity of organized meristem-derived micropropagated plants: A critical reappraisal

Summary The commercial multiplication of a large number of diverse plant species represents one of the major success stories of urilizing tissue culture technology profitably. Micropropagation has now become a multibillion dollar industry, practised all over the world. Of the various methods used to micropropagate plants, somatic embryogenesis and enhanced axillary branching have become the principal methods of multiplication. Long-term benefits of this enterprise, however, lie in the production of clonally uniform plants. The concept of genetic uniformity among micropropagated plants derived through organized meristems was exploded by several convincing reports of the incidence of somaclonal variation at morphological, cytological (chromosome number and structure), cytochemical (genome size), biochemical (proteins and isozymes), and molecular (nuclear and organellar genomes) levels. Somaclonal variation is not limited to any particular group of plants; it has been reported, for example, in ornamentals, plantation crops, vegetable and food crops, forest species and fruit trees. The upsurge of these reports, facilitated to a large extent by the technical developments made in molecular biology, is a matter of great concern for any micropropagation system. The economic consequences of somaclonal variation can be enormous in forest trees and woody plants, as they have long life cycles. Therefore, somaclonal variation has to be dispensed with if large-scale micropropagation of diverse plant species is to become not only successful but also accepted by end-users. In the light of the various factors (genotype, ploidy level, in vitro culture age, explant and culture type, etc.) that lead to somaclonal variation of divergent genetic changes at the cellular and molecular levels, genetic analysis of micropropagated plants using a multidisciplinary approach, especially at the DNA sequence level, initially and at various cultural stages, is essential. The results obtained at early multiplication stages from these tests could help in modifying the protocol/s for obtaining genetically true-to-type plants, and ultimate usage by entrepneneurs without any ambiguity.     

Analyzing somaclonal variation in micropropagated bananas (<Emphasis Type="Italic">Musa</Emphasis> spp.)

Summary In a micropropagation program, where it is of paramount importance to produce true-to-type planting material, somaclonal variation of any kind is undesirable. Variation among plants regenerated from tissue culture is termed ‘somaclonal variation’. In banana, somaclonal variants of different type have been reported with regard to plant morphology. This article discusses various factors due to which somaclonal variations may arise. Somaclonal variation may be detected by visual screening or by using molecular markers such as randomly amplified polymorphic DNA (RAPD), amplified fragment length polymorphism (AFLP), and by cytological studies. Although somaclonal variation is undesirable in the context of micropropagation, it can be used to advantage for genetic improvement of banana, as has been described.     

Selection and Analysis of Polymorphisms in Somaclonal Variants of <i>Agave americana</i> Resistant to <i>Fusarium oxysporum</i> via an Ethyl Methanesulphonate Treatment

Agave americana L. callus were exposed to different concentrations of ethyl methanesulphonate (EMS) 0, 15, 30, 45 and 60 mM and to different times of exposure (2 and 4 h). The viability and capacity of shoot formation were shown to be affected when the callus were exposed to high concentrations (30–60 mM). Only the callus exposed to 15 mM EMS presented shoot formation; the exposure time of two hours produced the largest quantity of shoots regenerated per callus (21 shoots/callus). In order to generate somaclonal variants resistant to Fusarium oxysporum, a selection pressure was applied through of a culture filtrate (CF) of 100 ppm of the fungus. This was made in callus obtained in the treatment with 15 mM EMS during 2 h of exposure. The CF caused oxidation and necrosis in 71.25% of the callus; however, they were capable of generating shoots (3.5 shoots/callus). Molecular markers type RAPD, ISSR and DAMD were used to evaluate the genetic variation arising from the mutations caused by EMS on control plants and 16-month-old somaclonal variants. The polymorphic information content (PIC) for each one of the initiating groups was: 0.28 (DAMD), 0.09 (ISSR) and 0.14 (RAPD). DAMD revealed a greater percentage of polymorphism than RAPD and ISSR. Polymorphic bands were detected in the somaclonal variants. This indicated that the EMS caused genetic variation in the regenerated plants conferring resistance to them against Fusarium oxysporum.     

Factors affectingin vitro shoot proliferation ofMyrtus communis L.: A comparison of adult and seedling material

Summary Two stocks of shoots growingin vitro, obtained from either seedlings or adult plants, were used to study the effects of material origin, the number of previous subcultures on the establishment medium, the explant type, and the macronutrients on shoot multiplication and elongation inMyrtus communis L., always in the presence of 4.4. μM benzyladenine (BA). Shoot proliferation was influenced mainly by stock origin, with higher responses from the adult material than from the seedling material, and by the number of subcultures, with the largest rates of multiplication and elongation in the first subculture. In the first subculture, the adult material was characterized by high rates of shoot multiplication and shoot elongation, and some shoots were hyperhydric. On the other hand, in the first subculture the seedling material was characterized by lower rates of shoot multiplication and elongation, and some shoots were affected by apical necrosis. In the third and the fifth subcultures, shoot multiplication and elongation declined in both materials, and hyperhydricity or apical necrosis were never found, although higher multiplication and elongation were consistently found for the adult material. The influence of the studied sources of variation is discussed in relation to shoot multiplication and elongation.     

Evaluation of genetic homogeneity of in vitro-raised plants of <Emphasis Type="Italic">Tecomella undulata</Emphasis> (Sm.) Seem. using molecular markers

Tecomella undulata (Sm.) Seem (family Bignoniaceae) is an economically and pharmaceutically important timber tree of arid regions of India. Overexploitation of natural stands coupled with minimal conservation and reforestation efforts has led to its incorporation in list of endangered species. This monotypic genus can be propagated only through seeds as no methods are available for its vegetative propagation. Therefore, protocol for multiplication of T. undulata via direct regeneration using nodal segments from mature trees has been standardized. Authentication of genetic homogeneity of these in vitro-raised plants is necessary for commercial-scale application of the developed micropropagation protocol. PCR-based molecular markers which have emerged as simple, fast, reliable, and labor-effective tools for testing the genetic homogeneity of in vitro-raised plants were used in the present study. Arbitrary (random amplified polymorphic DNA, RAPD), semi-arbitrary (inter-simple sequence repeat, ISSR; start codon targeted (SCoT) polymorphism), and sequence-based (simple sequence repeat, SSR) markers were used. DNA samples of shoots maintained in vitro for 2 years collected after every 4 subculture cycles (of 3 weeks each) and field-transferred plantlets were compared with the mother tree DNA using 131 primers (25 each of RAPD, ISSR, SCoT and 56 SSR). Scorable unambiguous and reproducible DNA fragments were produced by 77 (21 RAPD, 20 ISSR, 22 SCoT and 14 SSR) primers. A total of 71, 93, 94, and 42 distinct and scorable DNA fragments were produced by RAPD, ISSR, SCoT, and SSR primers respectively with an average of 3.38, 4.65, 4.27, and 3.0 DNA fragments per primer. The true-to-type nature of the in vitro-raised plants of T. undulata undergoing up to 32 subculture passages over a period of approximately 2 years was authenticated by monomorphic DNA fragments amplified with all primer combinations. Therefore, the developed micropropagation protocol can be safely used on a commercial scale for multiplying T. undulata plants.     

植物体细胞无性系变异研究进展

植物体细胞无性系变异是植物组织培养中的普遍现象,泛指在植物细胞、组织和器官培养过程中, 培养细胞和再生植株中产生的遗传变异或表观遗传学变异。植物体细胞无性系变异的发生有其遗传学基础, 可从形态学、细胞学、生物化学和分子生物学等多个方面对其进行综合检测和鉴定。植物体细胞无性系变异是植物育种的有利资源, 但同时也是植物微繁和遗传转化工作中需要克服的一大难题,一直被众多研究者所关注。本文分别从细胞学和分子生物学两个层次综述了植物体细胞无性系变异的遗传学基础及其鉴定方法的研究进展,并就其在植物品质改良中的应用现状、存在的问题和应用前景进行了讨论。     

Genetic stability of micropropagated almond plantlets,as assessed by RAPD and ISSR markers

Almond shoots produced by axillary branching from clone VII derived from a seedling of cultivar Boa Casta were evaluated for somaclonal variation using randomly amplified polymorphic DNA (RAPD) and inter-simple sequence repeats (ISSR) analysis. To verify genetic stability we compared RAPD and ISSR patterns of plantlets obtained after 4 and 6 years of in vitro multiplication. A total of 64 RAPD and 10 ISSR primers gave 326 distinct and reproducible band classes, monomorphic across all 22 plantlets analysed. Thus, a total of 7,172 bands were generated, exhibiting homogeneous RAPD and ISSR patterns for the plantlets tested. These results suggest that the culture conditions used for axillary branching proliferation are appropriate for clonal propagation of almond clone VII, as they do not seem to interfere with the integrity of the regenerated plantlets. These results allowed us to establish the use of axillary branching plantlets (mother-plants) as internal controls for the analysis of somaclonal variation of shoots regenerated from other in vitro culture processes performed with clone VII (adventitious regeneration, regeneration from meristem culture, virus sanitation programs and genetic engineering).M. Martins and D. Sarmento contributed equally to this paper     

Evaluation of genetic fidelity of in vitro raised plants of Dendrocalamus asper (Schult. & Schult. F.) Backer ex K. Heyne using DNA-based markers

Dendrocalamus asper, an edible bamboo is valued for its tender edible shoots in the food industry. However, overexploitation of natural stands of D. asper coupled with minimal conservation and reforestation efforts has led to its rapid depletion in nature. Therefore protocol for rapid multiplication of D. asper via direct regeneration using nodal segments from mature clumps was standardized and more than 25,000 plants were transferred to the field (Singh et al. 2012a). However, genetic fidelity of these in vitro raised plants needs to be authenticated for commercial scale application of the developed micropropagation protocol. PCR-based molecular markers have emerged as simple, fast, reliable and labor-effective tools for testing the genetic fidelity of in vitro raised plants. This study report the genetic fidelity analysis of in vitro raised plants of D. asper for the first time using arbitrary (Random Amplified Polymorphic DNA, RAPD), semi-arbitrary (Inter-Simple Sequence Repeat, ISSR; Amplified Fragment Length Polymorphism, AFLP), and sequence-based (Simple Sequence Repeat, SSR) markers. Bulked DNA samples of 20 in vitro raised shoots (collected after every three subculture cycles starting from 3rd to 30th passage) and field transferred plantlets were compared with the mother plant DNA using 90 primer combinations (25 each of RAPD, ISSR, SSR, and 15 AFLP) and scorable bands were produced by 78 (22 RAPD, 24 ISSR, 21 SSR, and 11 AFLP) primers. A total of 146 distinct and scorable bands were produced by 22 RAPD primers with an average of 6.6 bands per primer while the number of bands for ISSR primers varied from 3 (ISSR-4 and 9) to 13 (ISSR-17), with an average of 7.1 bands per primer. Similarly, SSR markers also showed wide variation in number of bands, ranging from 2 (RM 261) to 12 (RM 44, 140, and 224) with an average of 7.8 bands. AFLP primer combinations could generate 35–72 bands with an average of 48.7 bands per primer pair. Amplification of monomorphic bands with all primer combinations authenticated the true to type nature of the in vitro raised plants of D. asper which underwent up to 30 subculture passages over a period of approximately 2 years thereby supporting the commercial utilization of the developed micropropagation protocol.     

Assessment of genetic diversity in Colletotrichum falcatum Went accessions based on RAPD and ISSR markers

Sugarcane is susceptible to red rot disease caused by phytopathogenic fungus Colletotrichum falcatum Went which ultimately affect the economy of farmers as well as sugar based industry. One of the various ways to control this devastating disease is to develop disease resistance sugarcane cultivar and this requires the complete understanding of genetic makeup of pathogen. Although South Gujarat is well known sugarcane cultivating area, less published data can be found about PCR-based genetic diversity in prevalent C. falcatum accessions. So, present investigation aims at finding molecular variation among the ten accessions of C. falcatum using RAPD and ISSR molecular markers. A total of 35 RAPD and 39 ISSR primers were screened across 10 C. falcatum accessions, of which 15 RAPD and 21 ISSR primers have showed consistent amplification. Statistics related to genetic variation were estimated using NTSYS-PC by means of Dice’s coefficient. The results revealed 80.6% and 68.07% polymorphism and similarity coefficient ranged from 0.43 to 0.91 and 0.73 to 0.93 in RPAD and ISSR analysis respectively. The dendrogram generated using RAPD, ISSR and combined RAPD-ISSR grouped accessions into different clusters which reveal considerable level molecular variation among the C. falcatum accessions. It is also evident from PCA plots that accessions are rather dispersed with tested marker systems indicating good genetic base. So, in nut shell, we found considerable genetic variation and relatedness within C. falcatum accessions collected from different areas of south Gujarat, India using RAPD and ISSR markers.     

Foreed flushing of branch segments as a method for obtaining reactive explants of mature Quercus robur trees for micropropagation

The aim of this study was to micropropagate mature Quercus robur L. trees when material retaining physiologically juvenile characteristics (stump sprouts, epicormic shoots) is not available. Branch segments from 70–300 year-old trees were force-flushed and the flushed, partially rejuvenated or reinvigorated shoots were used as a source of explants for establishment of cultures. In vitro establishment and multiplication was achieved with seven of the eight selected trees. The proliferation capacity of cultures of vertically placed explants declined after several subcultures, but efficient shoot multiplication was achieved by culturing decapitated shoots placed horizontally on GD medium supplemented with 0.89 M of 6-benzyladenine. Reculturing the same horizontal explant several times allowed both higher multiplication rates and a shorter subculture cycle (2 weeks). An initial dark period of 5 days generally improved rooting capacity, which ranged, depending on clone, from 15 to 46%.Abbreviations BA 6-benzyladenine - GD Gresshoff and Doy Medium - IBA indole-3-butyric acid     

Micropropagation of Daylily (<i>Hemerocallis fulva</i>) from Crown-Tip Explants and Assessment of Somaclonal Variation of <i>in Vitro</i>-Propagated Plants Using SCoT Markers

Determination of the somaclonal variation of in vitro-propagated plants is crucial to determine the appropriate micropropagation protocol and growth regulators for commercial scale multiplication. In this research, nine multiplication media (MM) augmented with different concentrations of 6-benzyl adenine (BA), Kinetin (Kin), and Thidiazuron (TDZ), Three rooting media (RM) supplemented with three levels of α-naphthalene acetic acid (NAA) and three types of soil mixtures (v/v); Coco peat/Vermiculite/Sand (CVS), Peat moss/Perlite/Sand (PPS) and Peat moss/Perlite (PP) were used in the micropropagation protocol of daylily plants. MM2 showed the maximum shoot length and the number of leaves, while MM9 showed the maximum number of shoots. The RM1 showed the maximum root length and the number of roots. During acclimatization, CVS, PPS, and PP soil mixture showed similar performance except the CVS mixture showed lower performance regarding plant height and diameter. The genetic fidelity of micropropagated plants was evaluated using Start Codon Targeted (SCoT) Markers. Six SCoT primers amplified 51 scorable bands with an approximate range from 146 bp to 1598 bp size. Thirty one out of 51 loci were presented in the mother plants. 40 loci were polymorphic, 11 were monomorphic and 7 were unique. The amplification patterns of the micropropagated plants demonstrated genetic integrity to the mother plant ranging from 84.32 to 47.06 and somaclonal variations ranging from 52.94 with 5 mg/l BA pathway to 15.68 with 1mg/l TDZ pathway, thus demonstrating that the homogeneity and the variation of the micropropagated plants affected by the type and the quantity of the plant growth regulator used during multiplication subcultures. This research can be successfully used for other ornamental and medicinal plants’ bulk multiplication, germplasm conservation, and future genetic improvement.     

Genetic similarity among cultivars of Phyllostachys pubescens

Phyllostachys pubescens is the most important economic bamboo species in China, which grows widely in the South of China. There are more than ten cultivars in this species but their genetic relationship still remains unknown. We used both amplified fragment length polymorphism (AFLP) and inter-simple sequence repeat (ISSR) techniques to determine genetic similarity among ten cultivars of P. pubescens and two related species. Eight hundred and twenty seven bands, in which 495 are polymorphic, were detected using 15 pairs of AFLP primers whereas total 231 bands, in which 154 bands are polymorphic, were scored using 16 ISSR primers. Statistic analysis showed that the genetic similarity matrices obtained from these two sets of molecular markers had a significant correlation (R = 0.959, P = 0.013). The dendrogram generated with AFLP and ISSR markers could clearly genetically identify ten cultivars of P. pubescens that had high similarity with genetic distances ranging from 0.023 to 0.108, and could be divided into three groups based on their genetic variation and similarity. Our results suggest that these molecular markers are useful to genetically classify cultivars or varieties of a species, particularly a bamboo species.     

Effects of culture conditions on multiple shoot induction from inflorescence and RAPD analysis of cloned plants in Limonium sinensis (Girard) Kuntze, var. Golden Diamond

The optimum physical and chemical microenvironment for micropropagation of Limonium sinensis (Girard) Kuntze, var. Golden Diamond was established from immature inflorescence segments as explant. The highest frequency (62 %) of axillary shoot induction was obtained on MS medium (Murashige and Skoog Physiol Plant 15:473–497, 1962) supplemented with 8.88 μM BA, 1.34 μM of NAA and two growth additives cysteine (142.33 μM), and glutamine (684.22 μM). In the subsequent culture maximum average number of shoots (11.13?±?0.34) were obtained from micro-shoot explant on MS medium supplemented with the same additives and 2.22 μM BA. During subcultures the problem of vitrification was mitigated through increasing agar concentration from 0.8 % to 1.0 % and providing better ventilation. The in vitro developed shoots were rooted on MS medium supplemented with 2.46 μM IBA and 0.88 μM BA. Rooted plants were acclimatized successfully in the greenhouse with 80 % survival rate. RAPD analysis using 15 random decamer primers generated monomorphic banding pattern in micropropagated plants and similar to those of mother plant revealing the genetic integrity of regenerants.     

High frequency in vitro propagation of Phyllanthus amarus Schum. & Thom. by shoot tip culture

With the aim of micropropagation of Phyllanthus amarus, an important medicinal herb, shoot tips were cultured in Murashige and Skoog's medium supplemented with kinetin/ BAP singly or in combination with IAA. Growth regulators at lower range (0.1-1.0 mg L(-1)) stimulated direct regeneration of shoots. Kinetin was superior to BAP and kinetin-IAA combination was more suitable than kinetin alone. About 15 shoots were yielded per explant after 30 days of culture in the medium containing kinetin and IAA both at 0.1mg L(-1). The cluster of proliferated shoots elongated and rooted simultaneously under the same treatment following another subculture, thus shortening the total time schedule of micropropagation. Shoot tips of regenerated shoots were continuously used to regenerate new shoots with periodic transfer to fresh medium resulting in a steady supply of normal, healthy plants without any deviation in the production rate during a continuous one year culture. Micropropagated plants were successfully established in soil with high survivality (80%).