The effect of ventilation rate on proliferation and hyperhydricity of Dianthus caryophyllus L

Summary Comparative studies of carnation micropropagation under four different ventilation rates showed that using gas-permeable filters, with gelled or liquid media and modifying the volume of culture medium, it was possible to establish a suitable hydric state to obtain good proliferation rates with gelled and liquid medium, as well as optimal acclimatization of microcuttings. The following parameters were measured: ventilation rate, gas exchange coefficients, relative water loss, increase of agar concentration, micropropagation rates, percentage of hyperhydricity, and acclimatization rates. Our results confirm that it is possible to avoid hyperhydric plants cultured in liquid medium with the use of ventilated culture vessels through the control of the water relations during the multiplication phase and, at the same time, keeping the micropropagation rate.     

Shoot multiplication kinetics and hyperhydric status of regenerated shoots of gladiolus in agar-solidified and matrix-supported liquid cultures

In vitro shoot regeneration of gladiolus in three different culture systems, viz., semi-solid agar (AS), membrane raft (MR), and duroplast foam liquid (DF) cultures was evaluated following the kinetics of shoot multiplication and hyperhydricity at optimized growth regulator combinations. Compared to the AS system, matrix-supported liquid cultures enhanced shoot multiplication. The peak of shoot multiplication rate was attained at 18 days of incubation in the MR and DF systems, whereas the maximum rate in the AS system was attained at 21 days. An early decline in acceleration trend was observed in liquid cultures than the AS culture. The hyperhydric status of the regenerated shoots in the different culture systems was assessed in terms of stomatal attributes and antioxidative status. Stomatal behavior appeared to be normal in the AS and MR systems. However, structural anomaly of stomata such as large, round shaped guard cells with damage in bordering regions of stomatal pores was pronounced in the DF system along with a relatively higher K⁺ ion concentration than in the AS and MR systems. Antioxidative status of regenerated shoots was comparable in the AS and MR systems, while a higher incidence of oxidative damages of lipid membrane as evidenced from malondialdehyde and ascorbate content was observed in the DF system. Higher oxidative stress in the DF system was also apparent by elevated activities of superoxide dismutase, ascorbate peroxidase, and catalase. Among the three culture systems, liquid culture with MR resulted in maximum shoot multiplication with little or no symptoms of hyperhydricity. Shoots in the DF system were more prone to hyperhydricity than those in the AS and MR systems. The use of matrix support such as membrane raft as an interface between liquid medium and propagating tissue could be an effective means for rapid and efficient mass propagation with little or no symptoms of hyperhydricity.     

Regeneration of t Anthurium adventitious shoots using liquid or raft culture

This study was initiated to regenerate t Anthurium adventitious shoots, singly or in loose aggregates, by culturing homogenised inoculum in liquid or on the medium surface supported by a raft. The culture methods as compared to solid culture did not affect the time required for inoculum to regenerate. The regeneration rate was affected mainly by inoculum size, and it also influenced the regeneration frequency. All regenerated shoots were normal, without any sign of hyperhydricity. This revised version was published online in June 2006 with corrections to the Cover Date.     

Zeatin and TDZ-induced Shoot Proliferation and Use of Bioreactor in Clonal Propagation of Medicinal Herb, Roseroot (Rhodiola rosea L)

A procedure for in vitro propagation of roseroots (Rhodiola rosea L), a medicinal plant, was developed using a RITA bioreactor system containing liquid medium, combined with a gelled medium. Wild roseroot clones: ‘RCi’, ‘RC2’ and ‘RC3’ were established on a basal medium (BM) from in vitro-germinated seedlings on half-strength Murashige and Skoog (MS) salts. TDZ at 2–4 μM supported shoot proliferation but inhibited shoot elongation of ‘RCi’ shoots on gelled medium. Clones differed significantly with respect to multiplication rate with ‘RCi’ producing the most shoots per explant on gelled BM with 2 μM zeatin. In a bioreactor system, TDZ supported rapid shoot proliferation at lower concentration (0.5 μM) but induced hyperhydricity at more than 0.5 μM. Bioreactor-multiplied hyperhydric shoots of all clones when transferred to gelled medium containing 1–2 μM zeatin produced normal shoots within 4 wk of culture. Shoots were rooted in vitro on BM void of growth regulators. Almost all (9U to 95%) in vitro plantlets survived when transferred to potting medium.     

The effect of PlantformTM bioreactor on micropropagation of Quercus robur in comparison to a conventional in vitro culture system on gelled medium,and assessment of the microenvironment influence on leaf structure

Quercus robur L. was micropropagated by axillary bud proliferation testing two different shoot culture systems: (i) on gelled medium in Microbox (plastic vessel with a strip for ventilation) and (ii) in liquid culture in Plantform^TM bioreactor (a temporary immersion system). Two different conditions of temporary immersion were assessed: 12 min/8 h (Plantform 1) and 8 min/16 h (Plantform 2). The effect of the two culture systems was evaluated also during subsequent rooting phase, carried out on gelled medium. Finally, the influence of the different culture conditions on leaf structure was considered, taking also into consideration the micromorphological characters of young leaves from in-field-grown oaks. Nodal segments, excised from established in vitro shoots and cultured on modified Woody Plant Medium, showed a higher Relative Growth Rate in Plantform than in Microbox, but culture conditions provided in Plantform 1 favored shoot and leaf hyperhydricity. Shoots cultured in Microbox or Plantform 2 presented the same percentage of rooting after their transfer on gelled rooting medium. Leaves developed in the two different microenvironments had large stomata with elliptical shape, which indicates good functionality, and formed hairs, and epicuticolar waxes. These leaf features are considered to provide a good adaptability to ex vitro conditions.     

A two-step procedure for in vitro multiplication of cloudberry (<Emphasis Type="Italic">Rubus chamaemorus</Emphasis> L.) shoots using bioreactor

Cultures of three cloudberry (Rubus chamaemorus L.) clones collected from natural stands in Newfoundland and Labrador, Canada were established in vitro on a modified cranberry (Vaccinium macrocarpon Ait.) tissue culture medium containing 8.9 μM 6-benzylaminopurine (BAP). Clones were compared for in vitro shoot proliferation on gelled medium supplemented with varying levels of BAP and thidiazuron (TDZ). Addition of 5.8 μM gibberellic acid (GA₃) in 8.9 μM BAP-contained medium improved shoot proliferation. TDZ supported rapid shoot proliferation at low concentration (1.1 μM) but induced 20–30% hyperhydricity in a plastic airlift bioreactor system containing liquid medium. Bioreactor-multiplied hyperhydric shoots were transferred to gelled medium containing 8.9 μM BAP and 5.8 μM GA₃ and produced normal shoots within 4 weeks of culture. Genotypes differed significantly with respect to multiplication rate with ‘C1’ producing the most shoots per explant. Proliferated shoots were rooted on a potting medium with 65–75% of survivability of rooted plants. Present results suggested the possibility of large-scale multiplication of cloudberry shoots in bioreactors.     

Multiplication of <Emphasis Type="Italic">Chrysanthemum</Emphasis> shoots in bioreactors as affected by culture method and inoculation density of single node stems

Single node cuttings (1 cm in length) of Chrysanthemum were cultured on gelled and liquid media to compare shoot multiplication efficiency. Liquid culture resulted in greater fresh weight, dry weight, shoot length and leaf area compared to gelled culture. Shoots from liquid culture grew vigorously without hyperhydricity, showing 100% ex vitro survival. To determine optimal inoculation density of single nodes in a bioreactor, different numbers of single nodes (20 or 40 or 60 or 80) were placed into a 10-l column-type bioreactor. Shoot length was greatest at the 80-node inoculation, with the least number of branches, indicating the best inoculation density tested for shoot multiplication in bioreactors. In the final experiment, single-node cuttings in bioreactors were treated with three different culture systems: ebb and flood, deep flow technique (DFT) culture and immersion. Results indicated that the DFT culture led to the greatest fresh weight, shoot length and leaf area, followed by the ebb and flood culture, while the immersion culture suppressed shoot multiplication due to the lack of oxygen and the high water potential. Our results suggested the possibility of large-scale production of Chrysanthemum shoots in bioreactors.     

Hyperhydricity in shoot cultures of Scrophularia yoshimurae can be effectively reduced by ventilation of culture vessels

An effective procedure for obtaining healthy shoots from nodal segments of Scrophularia yoshimurae is described. Nodal segments cultured on Murashige and Skoog's (MS) basal medium supplemented with 1.0 mg L(-1) benzyladenine (BA) and 0.2 mg L(-1) alpha-naphthaleneacetic acid (NAA) induced multiple shoots in conical flasks that differed in the way they were closed and sealed. Hermitically sealed culture vessels resulted in high hyperhydricity/vitrification. High concentrations of ethylene and CO2 were found to accumulate in these vessels. The hyperhydricity of the shoot cultures could be decreased by progressively ventilating the vessels. Exchange of gases was achieved by removing the Parafilm sealing without affecting sterility. This reduced the hyperhydricity rate and gave a good recovery of vitrified shoots, but resulted in decreased proliferation and a dehydration of proliferating nodal segments and the culture medium. The best number of normal shoots was observed when the parafilm was removed for gaseous exchange after four weeks of culture incubation. The results show that hyperhydricity in shoot cultures of S. yoshimurae could be prevented by sufficient gas exchange during culture.     

Culture of Amelanchier x grandiflora in a programmable micropropagation apparatus

A micropropagation system was developed to test concepts for automation and microenvironment alteration. Amelanchier x grandiflora Rehd. Princess Diana (serviceberry) shoot cultures were grown in seven-liter polycarbonate containers. Through computer control, the apparatus intermittently applied culture medium to the plant material according to a selected schedule. Shoot growth in the programmable system was compared with four micropropagation treatments: gelled and liquid medium in baby food jars and gelled and non-cycling liquid medium in a seven-liter vessel. Plants cultured in continuous contact with liquid medium became increasingly vitrified. Significantly greater shoot number, shoot length, shoot weight, and culture weight occurred in the programmable system than in jars with gelled medium. The combination of liquid medium, 7-liter vessel, and intermittent contact with medium caused a significantly higher proliferation rate than any combination of jar/vessel and gelled/liquid medium tested.     

Natural ventilation effectively reduces hyperhydricity in shoot cultures of <Emphasis Type="Italic">Aloe polyphylla</Emphasis> Schönland ex Pillans

An investigation into the role of ventilation to reduce hyperhydricity in tissue cultures of Aloe polyphylla Schönland ex Pillans revealed that gaseous exchange between the in-vitro atmosphere and the outside environment is an essential prerequisite for controlling this disorder. In closed culture vessels, hyperhydricity affected as much as 84% of the newly-formed shoots on media gelled with gelrite. The leaves of hyperhydric shoots had a bright green colour, smooth epidermis and large, open stomata. Gaseous exchange was promoted by using modified lids with a hole covered with polyester or cotton mesh. In ventilated cultures, hyperhydricity was completely eliminated irrespective of the type of gelling agent used. Natural ventilation was further advantageous for the microplants in terms of leaf chlorophyll content as well as the deposition of epicuticular wax, indicating the onset of mechanisms that regulate water loss from the explants. Although culture ventilation was negatively correlated to the regeneration rate and shoot growth, it has the potential to control the appearance of abnormal phenotypes and can be easily adopted for routine A. polyphylla propagation in vitro.     

Comparison of methods of liquid medium culture for banana micropropagation

Five different liquid medium culture methods for meristem propagation of bananas were investigated and compared with solid medium culture. Treatments studied were: gelled culture medium (treatment 1); liquid medium with immersion of the plants (treatment 2); liquid medium with cellulose culture support (treatment 3); liquid medium with partial immersion of the plants (treatment 4); liquid medium aerated by bubbling (treatment 5); liquid medium with temporary immersion of the explants for 20 min every 2h (treatment 6). After 20 days of culture, three culture groups with statistically different multiplication rates were observed:

-shoots in simple liquid medium and those on cellulose substrate proliferated little or not at all,

-shoots on gelled medium, those subjected to partial immersion and those in aerated medium displayed multiplication rates of 2.2 to 3.1, and

-the highest multiplication rate (>5) was observed in explants subjected to temporary immersion in the medium.

Two groups of treatments differed in the accumulation of dry matter: the smallest weight (around 0.5 g) was observed in treatment 1, 2, 3 and 4, and accumulation was 2 to 5 times greater in the explants in aerated liquid medium and those subjected to temporary immersion. The highest multiplication rates and weight gains were observed in aerated treatments (treatments 4 and 5). Shoots in liquid medium continuously aerated by bubbling displayed hyperhydricity of the outer leaf sheaths. This was not observed with temporary immersion of explants.     

Adding gelling agents to cotton ovule culture media leads to subtle changes in fiber development

Summary Young cotton (Gossypium hirsutum) ovules will produce fiber in vitro when floated on a defined culture medium. Our laboratory is interested in examining the effects of altered gravity environments on fiber development as a model for the effects of gravity on cell expansion and cellulose biosynthesis. Since liquid culture media are unsuitable for altered gravity experiments, addition of gelling agents to cotton ovule culture media is necessary. In this study we have systematically examined the effects of four gelling agents at several concentrations on fiber production in culture. A rapid screening method using toluidine blue O staining indicated that after 3 wk in culture, fiber growth on 0.15% (wt/vol) Phytagel™ medium was similar to fiber growth on liquid medium. More detailed analysis of fiber development revealed that fiber length was not influenced by the addition of Phytagel™. Accumulation of cellulose, however, was reduced 50–60% compared with fibers produced in liquid media after 3 wk in culture. The fiber cellulose content rose with additional time in culture for both solid and liquid media treatments. By 4 wk in culture, the difference in cellulose content of fiber cell walls grown on solid versus liquid media was less than 20%. This variance in growth response on gelled media could be due to differences in media matric potential, to the immobility of ions trapped within the gel, or to toxicity of contaminants copurifying with Phytagel™. By identifying why ovule growth and fiber cellulose biosynthesis are reduced in cultures grown on gelled media, it will be possible to reveal new information about these processes in system that is less complicated than physiological systems at the whole plant level. Names of companies or commercial products are given solely for the purpose of providing specific information; their mention does not imply recommendation or endorsement by the U.S. Department of Agriculture over others not mentioned.     

Improvement of somatic embryogenesis in Hevea brasiliensis (Müll. Arg.) using the temporary immersion technique

Summary A culture procedure using temporary immersion in a liquid medium was tested for somatic embryogenesis of Hevea brasiliensis (Müll. Arg.). Embryogenic callus was placed under regeneration conditions, either on a gelled medium (Phytagel, Sigma, St. Louis, MO) or in a container designed for temporary immersion. The latter technique has some advantages over the use of a gelled medium during both the early steps of somatic embryogenesis, i.e., embryo development, and later on, i.e., during maturation, desiccation and germination. Somatic embryo production in a liquid medium was three to four times greater than on a semi-solid medium: 400 embryos/g fresh weight under the best embryogenesis induction conditions. Somatic embryogenesis had to be initiated on a gelled medium before the embryogenic callus was transferred to temporary immersion, and the amounts of 3,4- dichlorophenoxyacetic acid and N⁶-benzyladenine had to be reduced. Temporary immersion resulted in substantially more consistent, synchronized somatic embryo development, reducing the number of abnormal embryos by half and stimulating germination. All of the late events could be carried out in the temporary immersion container. Effective drying conditions were achieved after 12 wk without immersion and without selection of the embryos. Temporary immersion during germination greatly stimulated root development (+60%) and epicotyl emergency (+35%), combined with increased synchronization and a substantially reduced workload.     

Characteristics of strawberry plants propagated by in vitro bioreactor culture and ex vitro propagation method

Reproducible protocol for regeneration of complete plantlets from ‘Bounty’ strawberry (Fragaria ananassa Duch.), using a combination of gelled medium and bioreactor system, has been standardized. Sepals, leaf discs, and petiole halves produced multiple buds and shoots when cultured on semi solid‐gelled medium containing 4 μM thidiazuron (TDZ) for 4 wk followed by transferring in liquid medium containing 2 μM TDZ in a bioreactor system and cultured for another 4 wk. TDZ induced shoot proliferation at 0.1 μM in the bioreactor system but inhibited shoot elongation. TDZ‐induced shoots were elongated and rooted in vitro on gelled medium containing 2 μM zeatin. Such bioreactor‐derived tissue culture (BC) plantlets obtained from sepal explants were grown ex vitro and compared with those propagated by tissue culture on gelled medium (GC) and by conventional runner cuttings (RC), for growth, morphology, anthocyanin content, and antioxidant activity after three growth seasons. The BC and GC plants produced more crowns, runners, leaves, and berries than the RC plants although berry weight per plant did not differ significantly. BC and GC plants produced berries with more anthocyanin contents and antioxidant activities than those produced by the RC plants. However, intersimple sequence repeat (ISSR) marker assay produced a homogenous amplification profile in the tissue culture and donor control plants confirming the clonal fidelity of micropropagated plants. In vitro culture on TDZ and zeatin‐containing nutrient media apparently induced the juvenile branching characteristics that favored enhanced vegetative growth with more crown, runners, leaf, and berry production.     

Embryogenic suspensions of adult cork oak: the first step towards mass propagation

Protocols have been established to clone adult cork oak trees by somatic embryogenesis using semisolid medium. However, for economically viable mass propagation, embryogenic cultures in liquid medium need to be developed. In this study, suspension cultures were initiated from embryo clusters obtained by secondary embryogenesis on a gelled medium lacking plant growth regulators. After 6 days of culture, these embryo clusters generated high cell density suspensions that also contained small organized structures (embryos and embryogenic clumps). As the culture duration increased, tissue necrosis and fewer embryogenic structures were observed and the establishment of suspension cultures failed. An alternative method was found adequate for initiation of embryogenic suspensions: embryo clusters from gelled medium were briefly shaken in liquid medium and detached cells and embryogenic masses of 41–800 μm were used as inoculum. Maintenance of embryogenic suspensions was achieved using a low-density inoculum (43 mg l^?1) by subculturing four embryogenic clumps of 0.8–1.2 mm per 70 ml of medium. Proliferation ability was maintained for almost 1 year through ten consecutive subcultures. The initiation and maintenance protocols first developed for a single genotype were effective when tested on 11 cork oak genotypes.     

Effect of culture media and irradiance level on growth and morphology of Persea americana Mill microcuttings

Avocado shoots were multiplied in vitro in two culture media of different consistency, double phase and solid medium, at three different irradiance levels: 35, 60 and 85 μmol m⁻² s⁻¹. Effects of culture and environmental conditions in multiplication rate, rooting capacity, hyperhydricity and leaf surface morphology of microcuttings were evaluated. Double phase medium induced hyperhydricity, producing leaf microcuttings with deformed stomata and low crystalline epicuticular waxes; microcuttings also showed reduced rooting capacity. By contrast, solid medium promoted leaf area development on microcuttings and decreased hyperhydricity. Stomatal index was not affected by these treatments but stomatal density was, interacting with the amount of irradiance applied. Increasing irradiance decreased concentration of chlorophyll a and carotenoids in the leaf but did not affect leaf hyperhydricity. This revised version was published online in June 2006 with corrections to the Cover Date.     

Reduction of hyperhydricity in tissue cultures of oregano (Origanum vulgare) by extracellular polysaccharide isolated from Pseudomonas spp

Hyperhydricity or vitrification is a physiological malformation affecting tissue culture-based propagation of several plant species. A Pseudomonas spp-mediated approach was recently developed to control hyperhydricity in oregano. This bacterium-induced prevention of hyperhydricity helped the establishment of clonal plants in the greenhouse without extensive acclimatization. The prevention of hyperhydricity was specifically linked to mucoid Pseudomonas spp and was characterized by high chlorophyll and reduced water content in oregano shoots. The focus of research reported in this paper was to purify the extracellular mucoid component from Pseudomonas spp and evaluate the effect on hyperhydricity in oregano tissue culture. The extracellular mucoid component was purified by ethanol precipitation. This extracellular mucoid component was confirmed to be a polysaccharide using gas chromatography-mass spectrometry. The effect of purified polysaccharide to prevent or reduce hyperhydricity was tested in oregano clone 0–1. The polysaccharide prevented hyperhydricity in oregano with reduced efficiency compared to bacterial inoculation. This was characterized by higher chlorophyll and reduced water content when compared to uninoculated/untreated oregano shoots. This confirms that the Pseudomonas spp-mediated hyperhydricity reduction in oregano is partially due to its extracellular polysaccharide. This provides a novel approach to develop a media formulation to control hyperhydricity in wide number of plant species where tissue culture is used for clonal propagation.     

An efficient liquid culture system for tea shoot proliferation

The efficiency of thidiazuron in promoting tea shoot proliferation in liquid medium was evaluated. As compared to 6-benzyl adenine which induced hyperhydricity in the proliferated shoots in liquid medium, a progressive increase in the multiplication rate together with healthy shoot growth was achieved when thidiazuron (2.5 to 5.0 μM) was used instead of 6-benzyl adenine. Of the different liquid volumes compared in 250 ml Erlenmyer flasks, 20 ml was the most effective. While an increase in the multiplication rate coupled with normal but healthy shoots was observed under static and agitated conditions at this volume of liquid medium, hyperhydricity was induced in 50 ml liquid medium. Therefore, 20 ml static liquid medium with subculture periods at an interval six to eight weeks seems to be a cost and labour effective process as compared to the existing protocols involving solid media with subculture periods at 4 weeks interval. This revised version was published online in June 2006 with corrections to the Cover Date.     

Liquid medium and liquid overlays improve embryogenic tissue initiation in conifers

Somatic embryogenesis (SE) is expected to play an important role in increasing productivity, sustainability, and uniformity of future US forests. For commercial use, SE technology must work with a variety of genetically diverse trees. Initiation in loblolly pine (Pinus taeda L.), the main commercial US forest species, is often recalcitrant for desirable genotypes. Liquid initiation medium with no or low gelling agent or placement of the explant on gelled medium followed later by a liquid medium overlay during the initiation process increased initiation for loblolly pine and Norway spruce (Picea abies). Loblolly pine liquid medium required reduction of NAA from 2 mg/l in gelled medium to 0.3 mg/l in liquid medium. Once the NAA concentration was adjusted, loblolly pine initiation occurred in liquid medium with fully immersed megagametophytes, explants supported at the liquid medium surface, or on gelled medium overlaid with liquid medium. Liquid overlays (0.25 ml) consisting of medium with NAA reduced to 0.3 mg/l, 9 mg/l ABA and no gelling agent applied to explants on 2 ml of gelled medium provided excellent initiation results. Greatest initiation percentages occurred when the liquid overlay was applied 14 days after placement of the megagametophyte on gelled medium. Initiation increases ranged from +8.5% with high-value cross-pollinated seed sources to +6.5 to +9.9% with open-pollinated and often recalcitrant seed sources. Liquid medium addition allows rapid replenishment of nutrients and adjustment or change of pH, hormones, or other parameters without disturbing the tissue.     

Use of starch-gelled medium for tissue culture of some fruit crops

Six cultivars of apple and two of red raspberry consistently produced equal or significantly better shoot proliferation on modified Murashige and Skoog medium gelled with a mixture of corn starch and Gelrite than on the same medium gelled with agar. Two pear cultivars grown on starch-Gelrite medium produced hyperhydric shoots and almost no growth, but the addition of a polysaccharide hydric control (antivitrifying) agent to the medium eliminated hyperhydricity. The resulting shoot proliferation equaled or exceeded that on the agar-gelled medium. The starch-Gelrite mixture is easy to prepare and gelling agent costs are only 10–15% of agar, or less if starch is purchased in bulk. Although the opaque gray-white medium makes it more difficult to detect internal contaminants, external contaminants are easily discerned.The US Government's right to retain a non-exclusive royalty-free license on and to any copyright is acknowledged.