In vitro propagation of the neotropical giant bamboo, Guadua angustifolia Kunth, through axillary shoot proliferation

Guadua angustifolia Kunth was successfully propagated in vitro from axillary buds. Culture initiation, bud sprouting, shoot and plant multiplication, rooting and acclimatization, were evaluated. Best results were obtained using explants from greenhouse-cultivated plants, following a disinfection procedure that comprised the sequential use of an alkaline detergent, a mixture of the fungicide Benomyl and the bactericide Agri-mycin, followed by immersion in sodium hypochlorite (1.5% w/v) for 10 min, and culturing on Murashige and Skoog medium containing 2 ml l^?1 of Plant Preservative Mixture^®. Highest bud sprouting in original explants was observed when 3 mg l^?1 N⁶-benzylaminopurine (BAP) was incorporated into the culture medium. Production of lateral shoots in in vitro growing plants increased with BAP concentration in culture medium, up to 5 mg l^?1, the highest concentration assessed. After six subcultures, clumps of 8–12 axes were obtained, and their division in groups of 3–5 axes allowed multiplication of the plants. Rooting occurred in vitro spontaneously in 100% of the explants that produced lateral shoots. Successful acclimatization of well-rooted clumps of 5–6 axes was achieved in the greenhouse under mist watering in a mixture of soil, sand and rice hulls (1:1:1).     

Factors affecting micropropagation and acclimatization of an elite clone of Eucalyptus tereticornis Sm.

Several factors influencing micropropagation of a selected elite clone of Eucalyptus tereticornis Sm. were investigated. Amongst different cytokinins tested, 6-benzyleadenine proved to be the most effective cytokinin for shoot multiplication and elongation. The initial size of the shoot clump (inoculum) also influenced shoot multiplication and elongation. The number of shoots proliferated per culture vessel were significantly higher (342 shoots per culture vessel) when larger shoot clumps (15?C20 shoots) were inoculated, compared to smaller shoot clumps (4?C5 shoots), which resulted in a reduced shoot proliferation rates (245 shoots per culture vessel). However, the number of elongated shoots (65 per culture vessel) and shoot length (5.23?cm) were higher in cultures which were inoculated with smaller shoot clumps in comparison to those cultures which were inoculated with larger shoot clumps (54 shoots per culture vessel with shoot length of 4.17?cm). The maximum number of rooted shoots (80.7?%) was obtained on one fourth-strength MS medium supplemented with 5.0???M indolebutyric acid. The number of shoots proliferated, elongated, rooting frequency, and subsequent survival of plants after acclimatization were higher in cultures incubated under photosynthetically active radiation (PAR) compared to those incubated under cool fluorescent lights (CFL). Osmotic potential of the sap and chlorophyll content of cultures incubated under PAR were also higher than those incubated under CFL. Following transfer of plants to soil, inoculation with a suspension of Bacillus subtilis (plant growth-promoting bacterium) increased the survival rate of plants by 10?%, yielding successful transfer of 84?% of plants. Random amplified polymorphic DNA and inter simple sequence repeat analyses indicated a high level of clonal uniformity amongst regenerated plants and also with that of the mother plant.     

Effect of plant growth conditions, plating density, and genotype on the anther culture response of soft white spring wheat hybrids

Ten soft white spring wheat (Triticum aestivum L.) F₁ hybrids were grown under three temperature regimes, and anthers were cultured at two plating densities to investigate the effect of plant growth conditions, plating density, and genotype on embryo induction and plant regeneration. Anthers from plants grown at high temperature (25 °/18 °C) or from plants transferred from low (15 °/12 °C) to high temperature generally produced more embryos and green shoots, with a lower frequency of albinos, than did anthers from plants grown at low temperature. However, plating densities of 10 versus 20 anthers per milliliter, had little effect on anther response. Four of the five hybrids with `Fielder' as the female parent produced more embryos and green shoots than did hybrids with `AC Reed' as the female parent. Received: 12 July 1996 / Revision received: 1 April 1997 / Accepted: 30 April 1997     

Plant regeneration from immature seeds of Eugenia myrtifolia Sims.

Eugenia myrtifolia Sims. is an evergreen shrub, native to temperate and tropical rainforests of Australia, which is becoming an important containerized ornamental plant in the US and Mediterranean nursery industries. To satisfy the growing market demands for this new ornamental plant, development of an accelerated propagation method is required. The goal of this study was to investigate the in vitro regeneration potential of E. myrtifolia Sims. seeds at different stages of development, towards establishment of an in vitro multiplication system. Maximum regeneration of adventitious shoots was achieved from immature seeds cultured in the dark on half-strength Murashige and Skoog (MS) macronutrients and full-strength MS micronutrients and vitamins (MS/2) medium supplemented with 2.5 μM thidiazuron (TDZ). Induction of regeneration occurred after at least two successive subcultures on TDZ-enriched medium, followed by subcultures on expression medium (hormone free MS/2) or multiplication medium [MM; MS medium enriched with 4.4 M 6-benzyladenine and 0.05 M α-naphthaleneacetic acid], where complete development of shoots occurred. The regenerated shoots were excised and transferred again onto MM for micropropagation, where a proliferation rate of 1:4 was achieved, and finally the shoots were transferred to a hormone-free MS medium for rooting. Following ex vitro transplanting, acclimatization over a period of 15 d was sufficient to establish greenhouse plants. The regenerated plants grown in the field for more than 2 yr showed the same phenotype as that of mother plants. The adventitious regeneration and micropropagation carried out in this study can be used for a large-scale propagation and genetic engineering of E. myrtifolia Sims.     

An efficient system for high-quality large-scale micropropagation of Miscanthus × giganteus plants

Miscanthus?×?giganteus is a perennial grass considered to be one of the most promising biofuel and bioenergy crops because of its high biomass and quality, and low requirement for fertilizers and pesticides. Market demand for Miscanthus is rapidly increasing. However, M.?×?giganteus is a triploid that cannot produce viable seeds, and it has traditionally been propagated through rhizome division, which is low throughput and labor-intensive. Plant tissue culture provides the potential to propagate M.?×?giganteus in vitro while maintaining the original plant characteristics. Although protocols exist for M.?×?giganteus micropropagation, the multiplication rate and plant quality need to be improved to meet commercial demands. For this research, we have assessed callus induction, callus multiplication, plantlet regeneration, shoot multiplication, shoot quality improvement, rooting, plant acclimatization, and survival in the greenhouse and in the field. Through these studies, we have developed an efficient system for high-quality, large-scale micropropagation of M.?×?giganteus. The plants produced from our protocol exhibited more than 99% survival in soil due to the production of vigorous shoots and roots.     

Using LED lighting in somatic embryogenesis and micropropagation of an elite sugarcane variety and its effect on redox metabolism during acclimatization

This study investigated the ability of a light emitting diode (LED) to induce somatic embryogenesis (SE), shoot multiplication, and rooting of sugarcane (RB98710). We also accessed the effects on acclimatization. MS medium was used for all stages and was supplemented with different concentrations of growth regulators according to the culture stage. The material was maintained in a growth room under fluorescent (FL) or LED (82?% red, 18?% blue) lighting after rooting plants were acclimatized. We conducted both biometric and biochemical analyses before and after acclimatization. The LED conditions favored the formation of callus; however, the FL was more efficient at plant regeneration. A histological analysis showed the formation of somatic embryos occurred through direct and indirect pathways. The plants obtained through SE and grown under LED had a higher multiplication rate over six subcultures. Shoots rooted in both light sources, but the number of shoots and the weight gain of the roots were higher under LED. The malondialdehyde (MDA) level did not differ among treatments. Our results indicate the SE induction phase should be conducted under FL and the remaining micropropagation process should be performed using LED. After acclimatization the plants grown under LED did not change the SOD and CAT activities during the first 5 days, which suggests there was no acclimatization impact. The H₂O₂ and MDA values observed do not suggest damage to membranes. There was better development, lower water loss, and higher survival rate in plants from in vitro culture under LED conditions when compared to FL.     

Influence of thidiazuron (TDZ) pretreatment of shoot tips on shoot multiplication and ex vitro acclimatization of Harpagophytum procumbens

The effects of thidiazuron (TDZ) pretreatment of shoot tips on Harpagophytum procumbens shoot proliferation and successive stages of micropropagation, i.e. rooting of regenerated shoots and acclimatization of plantlets to ex vitro conditions, were described in the present study. The best response in terms of shoot proliferation (about seven shoots/explant) and shoot length (3.2 ± 0.4 cm) was obtained when explants pretreated with 25 µmol L^?1 TDZ for 6 h were cultured on Schenk and Hildebrandt medium containing indole-3-acetic acid (IAA) (0.57 µmol L^?1) and 6-benzylaminopurine (BAP) (8 µmol L^?1). Under these conditions, a 330 % increase in shoot multiplication over TDZ non-pretreatment culture was achieved and TDZ pretreatment shoots were longer compared to those in control culture (2.6 ± 0.3 cm). The TDZ pretreatment did not affect the percentage of rooted shoots, length of roots and number of roots formed per shoot. The rooted plantlets were transplanted from in vitro to pots with soil and grown during 1 year in the greenhouse. The hardening process was difficult and time-consuming. We found that the plants developed from the TDZ pretreated culture were superior to plants from non-pretreated culture in terms of survival rate and morphological features, such as shoot length, leaf size, flowering and earlier root tuberisation. Random amplified polymorphic DNA and inter-simple sequence repeat analyses of pretreatment with TDZ plants showed genetic similarity to non-pretreatment plants. We conclude that applying the strategy of initial explant pretreatment with TDZ may be valuable for the improvement in H. procumbens in vitro propagation.     

Changes in activity of antioxidant enzymes and photosynthetic machinery during acclimatization of micropropagated Cassia alata L. plantlets

The stimulatory effect of thidiazuron (TDZ) has been investigated in shoot multiplication for a simple, efficient, rapid, and commercially applicable regeneration protocol of an important medicinal plant, Cassia alata. Furthermore, the effects of an increased photosynthetic photon flux density (PPFD) on photosynthesis, the functioning of the photosynthetic apparatus, and the response of the antioxidant enzymatic system were studied during the ex vitro establishment of micropropagated plantlets. Multiple shoots were induced by culturing nodal explants excised from an aseptic seedling on Murashige and Skoog (MS) medium supplemented with various concentrations (1.0, 2.5, 5.0, 7.5, or 10.0 μM) of TDZ for different treatment durations (2, 3, 4, or 6 wk). The highest number of shoots (17.9?±?0.3) and longest shoot length (4.6?±?0.1 cm) were achieved when explants were exposed to 5.0 μM TDZ for 4 wk and subsequently subcultured on growth regulator-free MS medium for 8 wk. In vitro rooting of isolated shoots was best achieved on full-strength MS medium containing 0.5 μM indole-3-butyric acid (IBA). The micropropagated shoots with well-developed roots were successfully established in pots containing Soilrite? followed by garden soil and grown in greenhouse with an 85% survival rate. During the acclimatization period, significant changes in the activity of the antioxidant enzymatic system were observed. An increase in superoxide dismutase (SOD) activity was measured throughout the acclimatization period. Likewise an upregulation of catalase (CAT), ascorbate peroxidase (APX), and glutathione reductase (GR) enzyme activities were also observed. Pigment (chlorophyll a and b and carotenoids) content in ex vitro-formed leaves was significantly higher compared with those grown in vitro. These observed changes reflected the ability of plants to develop an antioxidant enzymatic defense system aiding in survival against oxidative stress and in reducing release of free radicals.     

Nitrogen utilization by Typha latifolia L. as affected by temperature and rate of nitrogen application

Greenhouse and growth chamber studies were conducted to evaluate growth and N utilization by Typha latifolia L. in flooded organic soil under varying temperatures and rates of N additions. Elevation of temperature from 10 to 25°C increased shoot biomass yields by 275%. Root biomass yields were lowest at 10°C and increased linearly as a function of temperature. Shoot/root ratios were low (0.72–0.82) at lower temperatures (10–15°C) and ratios increased by about three times at higher temperatures (20–30°C). Biomass yields were increased by addition of N fertilizers, while the shoot/root ratios were directly related to plant-available N present in the soil.Fertilizer ¹⁵N uptake (expressed as % of applied N) by the whole plant was 5.3% at 10°C, 37.5% at 20°C and at 30°C decreased to 20.8%. Fertilizer N accumulation in shoots was 2.1–29.8% of applied N, while roots accumulated 3.2–7.7%. Under greenhouse conditions, N uptake by T. latifolia was found to increase with increased rate of N application. Fertilizer N uptake by both shoots and roots was in the range of 61–77%. Plants cultured in growth chambers were affected by low light conditions resulting in poor growth and low fertilizer ¹⁵N uptake, as compared to plants grown under greenhouse conditions. Added fertilizer N was the major source of N during the early part of the growing season, while soil organic N was the major and perhaps the sole source of N during the latter part of the growing season.     

Endophytic bacteria isolated from orchid and their potential to promote plant growth

Twelve endophytic bacteria were isolated from the meristem of in vitro Cymbidium eburneum orchid, and screened according to indole yield quantified by colorimetric assay, in vitro phosphate solubilization, and potential for plant growth promotion under greenhouse conditions. Eight strains with positive results were classified into the genus Paenibacillus by FAME profile, and evaluated for their ability to increase survival and promote the growth of in vitro germinated Cattleya loddigesii seedlings during the acclimatization process. The obtained results showed that all strains produced detectable indole levels and did not exhibit potential for solubilizing inorganic phosphate. Particularly, an increase of the total biomass and number of leaves was observed. Two strains of Paenibacillus macerans promoted plant growth under greenhouse conditions. None of the treatments had a deleterious effect on growth of inoculated plants. These results suggest that these bacterial effects could be potentially useful to promote plant growth during seedling acclimatization in orchid species other than the species of origin.     

Photoautotrophic shoot and root development for triploid melon

The aim of this investigation was to establish environmental factors which promote growth and photosynthesis of melon (Cucumis melo L.) shoot buds, in vitro, and determine if photoautotrophic shoots had superior root forming ability in photoautotrophic environments. Buds from the triploid melon clone ‘(L-14×B)×L-14’ were observed for 21 days after transfer from a multiplication MS medium with 3% sucrose and 10 μM benzyladenine (BA) to a shoot development medium with 1 μM BA at three levels of sucrose in the medium (0, 1 and 3%), and light (50, 100 and 150 PPF) and CO₂ (500, 1000 and 1500 ppm) in the culture chamber. More shoot buds were observed with 3% sucrose in the medium. Increased light and CO₂ had a positive interaction with shoot proliferation. Fresh and dry weights were greatest at 3% sucrose, 150 PPF light and 1500 ppm CO₂. Shoot buds grew more slowly in sugar-free medium, but fresh and dry weight still doubled over 21 days of culture. Net photosynthetic rates (NPR) of buds were negative after four days in treatment conditions, but became positive after transfer to fresh, sugar-free medium. Two triploid genotypes of melon were (1) grown in vitro with sugar (photomixotrophic) and without sugar (photoautotrophic), (2) rooted in sugar-free media, both in a laboratory controlled environment chamber (in vitro) and a greenhouse acclimatization unit (ex vitro), and (3) compared for subsequent nursery growth in the greenhouse unit. The genotype ‘(L-14×B)×L-14’ produced more shoots than ‘(L-14×B)×Mainstream’ in both photomixotrophic or photoautotrophic conditions. ‘(L-14×B)×L-14’ rooted as well from either photoautotrophic and photomixotrophic shoots but ‘(L-14×B)×Mainstream’ rooted less frequently from photoautotrophic shoots. Seventy-six percent of the shoots in the laboratory controlled environment chamber were able to root photoautotrophically, whereas 47% of the shoots in the greenhouse acclimatization unit were rooted. Between 77% and 88% of plantlets from all treatment combinations survived transfer to the nursery. After growth in the nursery, the sizes of plants (fresh weight, dry weight, leaf area) were the same for either genotype, from either photoautotrophic or photomixotrophic shoots. Nursery plants that had been rooted in the laboratory controlled environment chamber were larger than those rooted in the acclimatization greenhouse chamber. This revised version was published online in June 2006 with corrections to the Cover Date.     

Micropropagation of Eucalyptus benthamii to form a clonal micro-garden

Eucalyptus benthamii is an important component of forestry plantations in cold regions, but it is difficult to obtain clonal plants of this species, especially by low rooting. In this study, we developed a method for cloning selected genotypes of E. benthamii using a micropropagation technique, enabling the formation of a clonal micro-garden. Nodal segments from sprouts of mini-stumps in the clonal mini-garden were used as explants. After in vitro establishment of the explants, we tested two selected clones (BP101 and BP118), three culture media (Wood Plant Medium (WPM), Correia and colleagues JADS medium, and Murashige and Skoog medium), and two plant growth regulators (6-benzylaminopurine (BAP) and ??-naphthaleneacetic acid (NAA)) for the multiplication of adventitious buds. Additionally, combinations of two other plant growth regulators (BAP and gibberellic acid (GA₃)) were tested for the elongation of shoots. The in vitro and ex vitro rooting of micro-plantlets prior to acclimatization were compared. The in vitro bud multiplication of E. benthamii depended on the clone, culture medium, and concentration of plant growth regulators. The best results were obtained with WPM supplemented with 0.5?mg?L^?1 BAP and 0.05?mg?L^?1 NAA. The elongation of shoots depended on the clone and plant growth regulator, and the best results were obtained with nutrient medium free of GA₃ and BAP. Histological analysis showed that both in vitro and ex vitro rooting were successful, resulting in normal development of adventitious roots showing a vascular connection with the vascular cambium. The new protocol is efficient for micro-plantlet production of E. benthamii and can be used for the formation of a clonal micro-garden for other Eucalyptus or tree species.     

Natural light as an alternative light source for the in vitro culture of banana (Musa acuminata cv. ‘Grande Naine’)

The concept of using sunlight for micropropagation systems is proposed as a way of reducing tissue culture costs. Shoot tips of Musa acuminata cultivar ‘Grande Naine’ were cultured in a non-controlled natural light environment at the IAEA Laboratories, Austria during summertime. Significantly more shoots were produced by plantlets cultivated in a sunlit room with photosynthetic photon flux densities (PPFD) fluctuating up to 570 μmol m-2 s-1, temperatures between 23 and 30 °C and photoperiods of 12 to 16-h, than by plantlets under artificial light in a growth chamber providing controlled conditions of a constant PPFD of 65 μmol m-2 s-1, temperatures ranging from 23 to 29 °C and a 16-h photoperiod. Highest multiplication rates were achieved in a greenhouse with PPFD reaching 860 μmol m-2 s-1 and temperatures of 18 – 43 °C, but browning of leaves and loss of turgor occurred. Nevertheless, rooted plantlets showed 100% survival during acclimatisation and normal development. Photoperiods of 12 – 16 h did not affect the multiplication rates. This revised version was published online in June 2006 with corrections to the Cover Date.     

In vitro conservation of chestnut (Castanea sativa) by slow growth

Slow growth storage has been achieved for Castanea sativa (cv. ‘Montemarano’) shoot cultures over a duration of 48 mo at a temperature of 8°C, where 82% of explants survived and were able to resume normal growth after transfer to standard culture conditions at 23°C. The evaluation of the chlorophyll content of leaves also showed no differences between material stored for 48 mo and control material subcultured at 23°C. With a storage temperature of 4°C, the survival of shoots was significantly lower at approximately 56% after 12 mo, and no plants recovered after 24-mo storage. The presence of 6-benzyladenine 0.44 μM in the culture medium proved to be necessary for the recovery of healthy shoots, while pre-treatments with different concentrations of abscisic acid did not significantly influence the survival of shoots following storage conditions. A low level of light during slow growth storage resulted in positive effects on the rate of shoot survival over the longest preservation periods.     

Rapid in vitro micropropagation of Agapanthus praecox

In vitro micropropagation and acclimatization for the ornamental Agapanthus praecox, are reported. The influence of different growth regulators on shoot multiplication from shoot-tip explants of A. praecox was investigated. Prolific shoot multiplication (47.3 ± 1.96 shoots per explant) was achieved on Murashige and Skoog (MS) medium supplemented with 22.2 μM benzyladenine (BA), 2.9 μM indole-3-acetic acid (IAA), and 4.5 μM thidiazuron (TDZ). Shoots were rooted on half-strength MS basal medium supplemented with 5.7 μM IAA and 2.5 μM 2-isopentenyladenine (2iP) with 11.3 ± 0.78 roots per shoot. The in vitro-raised plants were established successfully in a 1:1 (v/v) vermiculite:sand mixture when maintained in a greenhouse with 100% survival. The elongated shoots (more than 5 cm in length) were treated for rooting and acclimatization in a moistened (5.7 μM IAA and 2.5 μM 2iP) vermiculite:sand (1:1 v/v) mixture, first in the misthouse and then in the greenhouse. Rooting and acclimatization was achieved simultaneously (100%) in the misthouse which was followed by greenhouse cultivation. This system can be used for rapid mass clonal propagation of A. praecox, for conservation strategies, commercial production, gene transformation studies and to produce phytomedicines.     

The effect of root temperature on rose plants in relation to air temperature

Rose plants (Rosa hybrida ‘Sonia’=‘Sweet Promise’) were grown in heated (minimum night temperature 17°C), and unheated greenhouses with or without root heating to 21°C. These trials covered 6 growth cycles extending over two winter seasons. In the heated greenhouse, root heating did not increase yield, flower quality or plant development. In the unheated greenhouse, root-heated plants grew as well as those in the air-heated greenhouse as long as the air temperature did not fall below 6°C. When minimum night temperatures fell below 6°C, growth, yield and quality were reduced, irrespective of root temperature. Daytime plant water relations were studied in plants growing at 6 different root temperatures in the unheated greenhouse. Leaf resistance to water diffusion was lowest at optimal root temperature. Total leaf water potential was not significantly affected by root temperature.     

In vitro propagation of Cuphea procumbens Orteg. and Evaluation of genetic fidelity in plantlets using RAPD marker

An efficient, rapid and reproducible plant regeneration protocol was successfully developed for Cuphea procumbens Orteg. using cotyledonary node explants excised from 15?days old aseptic seedlings. A range of cytokinins were investigated for multiple shoot regeneration. Of the three cytokinins, 6-benzyladenine (BA), Kinetin (Kin) and 2-isopentenyl adenine (2-iP) evaluated as supplement to Murashige and Skoog (MS) medium, BA at a concentration of 2.5???M was effective in inducing multiple shoots. The highest number of multiple shoots (9.33?±?0.60) and maximum average shoot length (4.16?±?0.44?cm) was standardized on MS medium supplemented with 2.5???M BA alongwith 0.5???M NAA. Addition of 200?mg/l Casein hydrolysate (CH) to the shoot induction medium enhanced the growth of regenerants. Rooting of in vitro regenerated shoots was best achieved on 1/2 strength MS medium. The in vitro raised plantlets with well developed shoots and roots were hardened, successfully established in earthen pots containing garden soil and maintained in greenhouse with 80% survival rate. Randomly Amplified Polymorphic DNA (RAPD) markers were used to evaluate the genetic stability among in vitro regenerated progenies. All RAPD profiles from the micropropagated plants were monomorphic and similar to control plant. These results suggests that the culture conditions used for the axillary bud proliferation are appropriate for clonal propagation of this medicinally important plant as they do not appear to interfere with genetic integrity of in vitro regenerated plants. The described method can be successfully employed for large-scale multiplication and in vitro conservation of C. procumbens.     

Inhibited Long-Distance Movement of Potato Leafroll Virus to Tubers in Potato Genotypes Expressing Combined Resistance to Infection, Virus Multiplication and Accumulation

Plants of two potato clones which, in preliminary greenhouse assessments, showed resistance to multiplication and accumulation of potato leafroll virus (PLRV) were graft or aphid inoculated with the virus and grown in the greenhouse; plants of a moderately susceptible cultivar were used for comparison in all experiments. A high concentration of aphid‐borne inoculum was used to ensure strong infection pressure. Clone M62759 appeared to be highly resistant to PLRV infection, whereas clone PS1706 was more susceptible. Both clones expressed a high level of resistance to virus multiplication, when primary or secondary infection was assayed by enzyme‐linked immunosorbent assay. Moreover, PLRV was detected in only few or none of the progeny plants of clone M62759, which thus strongly inhibited virus transport to tubers. The study on PLRV translocation from aphid‐inoculated shoots to uninoculated shoots sprouted from the same tubers showed that no specific mechanisms are likely to impair PLRV movement through the tubers of the resistant genotypes. These results indicate that three valuable components of the resistance to PLRV are probably closely linked in the genotype, a combination that seems to occur rather rarely in potato clones. Nevertheless, selecting potato genotypes for the complex resistance to PLRV may prove to be a worthwhile part of breeding programmes, provided that the genetic mechanisms governing particular types of resistance are better recognized.     

An efficient micropropagation system for Tylophora indica: an endangered, medicinally important plant

An efficient protocol is described for the rapid in vitro multiplication of an endangered medicinal plant, Tylophora indica (Burm. f.) Merrill, via enhanced axillary bud proliferation from nodal explants collected from young shoots of a two-year-old plant. The physiological effects of growth regulators [6-benzyladenine (BA), kinetin (Kin) thidiazuron (TDZ), indole-3-acetic acid (IAA), indole-3-butyric acid (IBA) or α-naphthalene acetic acid (NAA)], ascorbic acid (AA), different strengths of Murashige and Skoog (MS) medium and various pH levels on in vitro morphogenesis were investigated. The highest number (8.6 ± 0.71) of shoots and the maximum average shoot length (5.2 ± 0.31 cm) were recorded on MS medium supplemented with 2.5 μM BA, 0.5 μM NAA and 100 mg/l AA at pH 5.8. Rooting was best achieved on half-strength MS medium augmented with 0.5 μM IBA. The plantlets regenerated in vitro with well-developed shoot and roots were successfully established in pots containing garden soil and grown in a greenhouse with a 90% survival rate. The regenerated plants did not show any immediate detectable phenotypic variation. The described method can be successfully employed for large-scale multiplication and long-term in vitro conservation of T. indica.     

The effect and transmission of one isolate of the rust Puccinia minussensis on five clones of Lactuca sibirica

In a greenhouse experiment, one isolate of the systemic rust fungus Puccinia minussensis was applied to the host clone from which it was collected and to four other clones of the host Lactuca sibirica. The plants were grown in fertilized potting compost (N+) to promote growth and in peat (N-) to hamper growth, for three growing periods during one year. The results show that the expression of host plant resistance could not be determined visually, but there were differences in effects on the clones. The rust isolate was found to produce a significantly higher percentage of diseased shoots on clone A (the clone it was taken from). Furthermore, the rust also had the strongest effect on both biomass and shoot production on clone A compared to the other four clones. The data suggest that the rust isolate is highly adapted to the clone from which it originated. We suggest that selection in this system has not favoured a benign pathogen and that similar patterns are likely to occur for plants that (i) rarely establish by seeds; (ii) have strong lateral growth; and (iii) may persist for long periods once established.