Production of 2-phenylethanol and 2-phenylethylacetate from L-phenylalanine by coupling whole-cell biocatalysis with organophilic pervaporation

An integrated bioprocess for the production of the natural rose-like aroma compounds, 2-phenylethanol (2-PE) and 2-phenylethylacetate (2-PEAc), from L-phenylalanine (L-phe) with yeasts was investigated. The hydrophobicity of the products leads to product inhibition, which can be compensated by in situ product removal (ISPR). An organophilic pervaporation unit, equipped with a polyoctylmethylsiloxane (POMS) membrane, was coupled via a bypass to a bioreactor and proved to be a suitable technique for the in situ removal of high-boiling products from culture broth. With batch cultures of the thermotolerant yeast Kluyveromyces marxianus CBS 600 in a standard medium at 35 degrees C, the use of pervaporation resulted in a double 2-PE concentration (2.2 g/L) and 1.3 g/L 2-PEAc, which only accumulated transiently in low concentrations during cultivation without ISPR. Using a previously optimized medium, the variation of the temperature from 30 degrees C to 40 degrees C caused an increase in the total conversion yield from 63% to 79%, corresponding to total product concentrations of 5.23 and 5.85 g/L, respectively. In the 40 degrees C batch experiment, the volumetric productivity (2-PE + 2-PEAc) during the exponential phase was 5.2 mmol/L h. While for 2-PE, there is still potential for further optimization, the more hydrophobic 2-PEAc was nearly completely removed from the aqueous culture broth (enrichment factor >400), resulting in highly aroma-enriched permeates. Due to the temperature-correlated performance of the pervaporation, the bioconversion was still efficient even at 45 degrees C (conversion yield: 69%). Surprisingly, at 45 degrees C, the molar ratio of the two products inverted and 2-PEAc turned out to be the main product (4.0 g/L), which opens easy control of the reaction's selectivity by external means. Retrofitting the process with interim heating and cooling equipment to use different temperature levels for cultivation and pervaporation resulted in a decreased yield and product concentration caused by multiple stress factors. The medium composition affected the pervaporation efficiency with molasses acting detrimental.     

Increased productivity of <Emphasis Type="Italic">Clostridium acetobutylicum</Emphasis> fermentation of acetone,butanol, and ethanol by pervaporation through supported ionic liquid membrane

Pervaporation proved to be one of the best methods to remove solvents out of a solvent producing Clostridium acetobutylicum culture. By using an ionic liquid (IL)-polydimethylsiloxane (PDMS) ultrafiltration membrane (pore size 60 nm), we could guarantee high stability and selectivity during all measurements carried out at 37°C. Overall solvent productivity of fermentation connected with continuous product removal by pervaporation was 2.34 g l⁻¹ h⁻¹. The supported ionic liquid membrane (SILM) was impregnated with 15 wt% of a novel ionic liquid (tetrapropylammonium tetracyano-borate) and 85 wt% of polydimethylsiloxane. Pervaporation, accomplished with the optimized SILM, led to stable and efficient removal of the solvents butan-1-ol and acetone out of a C. acetobutylicum culture. By pervaporation through SILM, we removed more butan-1-ol than C. acetobutylicum was able to produce. Therefore, we added an extra dose of butan-1-ol to run fermentation on limiting values where the bacteria would still be able to survive its lethal concentration (15.82 g/l). After pervaporation was switched off, the bacteria died from high concentration of butan-1-ol, which they produced.     

Anaerobic degradation of trans-cinnamate and ω-phenylalkane carboxylic acids by the photosynthetic bacterium Rhodopseudomonas palustris: evidence for a β-oxidation mechanism

The mechanism responsible for the initial steps in the anaerobic degradation of trans-cinnamate and -phenylalkane carboxylates by the purple non-sulphur photosynthetic bacterium Rhodopseudomonas palustris was investigated. Phenylacetate did not support growth and there was a marked CO₂ dependence for growth on acids with greater side-chain lengths. Here, CO₂ was presumably acting as a redox sink for the disposal of excess reducing equivalents. Growth on benzoate did not require the addition of exogenous CO₂. Aromatic acids with an odd number of side-chain carbon atoms (3-phenylpropionate, 5-phenylvalerate, 7-phenylheptanoate) gave greater apparent molar growth yields than those with an even number of side-chain carbon atoms (4-phenylbutyrate, 6-phenylhexanoate, 8-phenyloctanoate). HPLC analysis revealed that phenylacetate accumulated and persisted in the culture medium during growth on these latter compounds. Cinnamate and benzoate transiently accumulated in the culture medium during growth on 3-phenylpropionate, and benzoate alone accumulated transiently during the course of trans-cinnamate degradation. The transient accumulation of 4-phenyl-2-butenoic acid occurred during growth on 4-phenylbutyrate, and phenylacetate accumulated to a 1:1 molar stoichiometry with the initial 4-phenylbutyrate concentration. It is proposed that the initial steps in the anaerobic degradation of trans-cinnamate and the group of acids from 3-phenylpropionate to 8-phenyloctanoate involves -oxidation of the side-chain.Abbreviation 3-PP 3-phenylpropionic acid - 4-PB 4-phenylbutyric acid - 5-PV 5-phenylvaleric acid - 6-PH 6-phenylhexanoic acid - 7-PH 7-phenylheptanoic acid - 8-PO 8-phenyloctanoic acid - 4-P2B 4-phenyl-2-butenoic acid - GC/MS Gas chromatography/Mass spectrometry - HPLC High-pressure liquid chromatography     

Molecular insights into substrate binding mechanism of undecaprenyl pyrophosphate with membrane integrated phosphatidyl glycerophosphate phosphatase B (PgpB) using molecular dynamics simulation approach

Undecaprenyl phosphate (C55-P) acts as carrier lipid in the synthesis of peptidoglycan, which is de novo synthesized from dephosphorylation of undecaprenyl pyrophosphate (C55-PP). The phosphatidylglycerol phosphate phosphatase B (PgpB) catalyzes the dephosphorylation of C55-PP and forms C55-P. As no structural study has been made regarding the binding of C55-PP to PgpB, in the current study, in silico molecular docking, followed by 150 ns molecular dynamics simulation of the putative binding complex in membrane/solvent environment has been performed to understand conformational dynamics. Results are compared with simulated apo form and PE inhibitor-bound form. Analysis of correlated residual fluctuation network in apo form, C55-PP bound and PE inhibitor-bound form suggests that difference in dynamic coupling between TM domain and α2 and α3 helix of periplasmic domain provides ligand binding to facilitate catalysis or to show inhibitory activity. Distance distribution in catalytic residual pair, H207-R104; H207-R201 and H207-D211 which stabilizes phosphate-enzyme intermediate shows a narrow peak in 2.4–3.6 Å in substrate-bound compared to apo form. Binding interactions and binding free energy analyses complement the partial inhibition of PE where PE has less binding free energy compared to the C55-PP substrate as well as the difference in binding interaction with catalytic pocket. Thus, the present study provides how substrate binding couples the movement in TM domain and periplasmic domain which might help in the understanding of active site communication in PgpB. C55-PP phosphatase interactions with a catalytic pocket of PgpB provide new insight for designing drugs against bacterial infection.     

Pervaporation performance of a composite bacterial cellulose membrane: dehydration of binary aqueous–organic mixtures

Summary Acetobacter xylinum (Gluconacetobacter xylinus) is a bacterium that produces extracellular cellulose under static culture conditions. The highly reticulated cellulose matrix along with the entrapped cellulose-forming bacteria is commonly referred to as a pellicle. The processed bacterial cellulose membrane/film was modified into a composite bacterial cellulose membrane (CBCM) for pervaporation separation of aqueous–organic mixtures. The CBCM was prepared by coating with alginate or alginate+polyvinylpyrrolidone and cross-linking with glutaraldehyde. The pervaporation performance was determined using aqueous–organic mixtures such as, 1:1 (v/v) water–ethanol, water–isopropanol and water–acetone. The pervaporation performance of the CBCM was more effective for zeotropic mixtures (water–acetone) in comparison to the investigated azeotropic mixtures (water–ethanol and water–isopropanol). The selectivity of CBCM was found to be 4.8, 8.8, 19.8 for water–ethanol, water–isopropanol and water–acetone mixtures, respectively. The permeation flux for the water–acetone mixture was found to be 235 ml/m²/h. The present investigation demonstrated that the CBCM could be employed to concentrate azeotropic as well as zeotrope forming binary mixtures by preferential pervaporation of water, with low energy requirements in contrast to the established method of distillation. In addition, the effects of feed composition, operating temperature, membrane thickness, and method of CBCM preparation on pervaporation performance have been evaluated. Investigations with the CBCM revealed that 94.5% ethanol, 98% acetone and 98.5% isopropanol concentrations could be attained from the initial 50% aqueous mixtures of these chemicals by way of pervaporation. In the case of the isopropanol–water mixture the resolving property of the membrane was more evident as the concentration arrived at was 98.5%, in contrast to other binary mixtures. The surface characteristics of the CBCM were revealed by scanning electron microscopy. In view of its properties the CBCM can be useful for pervaporation separation of these chemicals at moderate temperatures and pressure. The CBCM could be employed in the downstream processing of heat-labile and flavor-imparting volatile molecules in the field of food biotechnology and fabrication of membrane bioreactors for on-line product purification. Further studies are under progress to use the membrane for the immobilization of food processing enzymes.     

Recovery of intestinal membrane binding sites for K88 E. coli from pig mucosal organ cultures

Summary Putative receptors for K88+ E. coli from piglet intestinal epithelium were released into the organ culture medium and were demonstrated by direct binding with K88+ E. coli through the utilization of an in vitro binding procedure or by immunoprecipitation with K88 antigen.Incorporation of ¹⁴C-glucosamine by newborn to day old and 3-week to 6-week old piglet jejunal and ileal mucosa, in organ culture, occurred throughout the 24 hr culture period. Uptake in both age groups and both areas of the intestine was similar with a somewhat greater incorporation by the older age group.Secretion of ¹⁴C-glucosamine-labeled components into the culture medium was demonstrated by gel filtration of the concentrated medium. Some large molecular weight components eluted in the void volume in excess of 2 x 10⁶ daltons. A second peak of activity was spread from approximately 690K to 25K daltons. All eluted fractions demonstrated binding to K88+ E. coli.Antibodies to purified brush borders from susceptible pigs produced prominent precipitation bands following double diffusion with concentrated organ culture media which confirmed that the organ culture media contained labeled proteins of brush border origin.Immunoprecipitation of the intestinal mucosal organ culture media with K88+ pili and pilus antisera, followed by electrophoresis with SDS and reduced conditions, demonstrated a subunit of approximately 35K daltons.     

Plant regeneration by organogenesis in Vitis rootstock species

A procedure for the regeneration of Vitis rootstocks plantlets by organogenesis from foliar tissues is described. Leaves from mature plants grown in growth chambers or from plantlets grown in tubes were wounded with a scalpel and cultured on a modified Murashige and Skoog liquid medium containing different concentrations of benzyl-aminopurine. The presence of benzyl-aminopurine is required for shoot formation. The age of the source explant, the composition of the culture medium and the culture temperature are important parameters of the regeneration process.Abbreviations BA 6-benzyl-aminopurine - MS Murashige and Skoog medium - MM modified Murashige and Skoog medium     

In vitro propagation ofMedicago andLotus species by node culture

Summary Nodes ofMedicago sativa, Lotus corniculatus, Lotus tenuis, andLotus pedunculatus were cultured on MS basal media with different growth regulators. InM. sativa each node produced one shoot and the apical dominance was unaffected by high levels of cytokinins, and subsequent cycles of culture. Shoot development was stimulated by the presence ofN ⁶-isopentenyl-adenine in the culture medium and was dependent on the genotype of the explant. Shoot development was not affected by the original position of the node on the plant nor by the plant age. Shoots rooted in MS medium gelled with starch and containing 2 mg·liter⁻¹ indol-3-acetic acid. In the threeLotus species, node culture was a more effective technique than inM. sativa. The number of shoots per node increased with the time of culture and with the presence of 0.05 mg·liter⁻¹ of 6-benzylaminopurine. The highest number of shoots derived from one node was achieved inL. pedunculatus and inL. tenuis by culturing single nodes, whereas inL. corniculatus stem segments had to be totally covered by the medium for success. Rooting was easily achieved in MS medium with or without auxins.     

Proliferation and differentiation of primary bovine myoblasts using Chlorella vulgaris extract for sustainable production of cultured meat

Recently, cultured meat obtained from livestock-derived cells is being considered as a sustainable food source that reduces the use of natural resources. This study aimed to show that nutrients extracted from Chlorella vulgaris were beneficial in the culture of primary bovine myoblasts (PBMs), a major cell source for cultured meat production. Nutrients (glucose, amino acids, and vitamins) present in the animal-cell culture media were effectively recovered from C. vulgaris using acid hydrolysis treatment. On culture in nutrient-free inorganic salt solution, cell death was induced in most PBMs after 6 days of cultivation. However, the addition of C. vulgaris extract (CVE) significantly improved PBM viability, which was comparable to the viability in conventional culture medium (Dulbecco's modified Eagle's medium). Furthermore, by adding horse serum to induce differentiation, the formation of myotubes was confirmed when CVE were used. Together, the results showed that CVE could be used as an alternative to the conventional culture medium for PBMs. These findings will not only lower the environmental risks associated with the establishment of this eco-friendly cell culture system, but also highlight microalgae as a potent nutrient source that can replace conventional grain-dependent nutrient sources.     

Experimental Microbial Populations Thirty-five Years Later: The Influence of Food on the Symbiosis of Paramecium aurelia Syngen 4, 51.7

Changes in the nutrition of Paramecium aurelia affect its ability to serve as host for the bacteroid parasite, kappa, and the presence or absence of kappa affects its ability to grow in axenic culture. Loss of kappa, tested by the presence or absence of killer reaction, occurred in cultures of P. aurelia growing at a reduced division rate on autoclaved Enterobacter aerogenes in suspensions of lettuce and yeast autolysate 14–17 days after they had been rendered bacteria-free by washing. Killer Paramecium sterilized of bacteria by treatment with an antibiotic mixture of penicillin-G and streptomycin in combination with a nonbacterial nonliving culture medium, lost the ability to kill after from 6 to 48 hours in the sterilizing medium. The ciliates from which kappa had been lost during exposure to antibiotics could be transferred immediately and maintained in axenic culture, but those washed free of bacteria could not be maintained axenically until kappa had been lost during cultivation in a medium containing killed bacteria. It is suggested that a knowledge of the nutritional requirements of symbiotic microorganisms is essential for understanding the ecological aspects of eutrophication of aquatic environments.     

A study of karyotypes and their alterations in cultured and Agrobacterium transformed roots of Lycopersicon peruvianum Mill

Summary Organ culture, plant regeneration from callus culture, and hairy root disease caused by Agrobacterium rhizogenes were utilized as methods of rapid in vitro propagation in Lycopersicon peruvianum Mill. A detailed and comparative karyotype analysis of the resulting material under such in vitro conditions revealed karyotypic stability under organ culture method, ploidy change in callus derived plants, and minor structural alterations of chromosomes in roots transformed by A. rhizogenes.Abbreviations BAP N6-benzylaminopurine - NAA naphthaleneacetic acid - MS Murashige and Skoog medium - RG regeneration medium - SDS sodium dodecyl sulfate     

Regeneration of fertile green plants from oat isolated microspore culture

Regeneration of fertile green plants from isolated oat microspores is reported for the first time. Factors critical for microspore growth and regeneration include cold pre-treatment, pH of culture medium and the use of conditioned culture medium. It was found that cold pre-treatment at 4°C in the dark for a minimum of 6 weeks was necessary to consistently achieve microspore growth into multicellular structures (MCS). Longer pre-treatments of up to 9 weeks were tested and found to be positively correlated with the number of MCS produced. Microspore culture medium with pH 8.0 produced significantly more MCS larger than eight cells in size than media with pH 5.8. The use of medium conditioned by actively growing barley microspores significantly increased the numbers of MCS larger than eight cells in size compared to non-conditioned media. Plants were regenerated only from cultures using conditioned medium. A total of 2 green plants and 15 albinos were regenerated. Of the green plants, one had the haploid chromosome complement (n = 3x = 21) and the other had the parental hexaploid chromosome complement (2n = 6x = 42) which may be due to spontaneous chromosome doubling. The hexaploid plant set seed naturally and the haploid plant set seed after its chromosome complement was doubled with colchicine.     

Nutritional and gibberellic acid requirements in kiwifruit vitroponic cultures

Summary Residual macronutrients, carbon source, and gibberellic acid (GA₃) in the culture medium were measured throughout the whole culture period of kiwi (Actinidia deliciosa Chev. cv. Hayward) explants cultured in liquid medium using cellulose plugs as explant support. The objective of this study was to adapt the composition of the culture medium to an automated culture system with the possibility of applying 6-benzyladenine pulses so as to improve the efficiency of kiwifruit micropropagation. Ammonium and phosphate were the most consumed ions at the end of the culture period (35 d). Murashige and Skoog medium might be too rich for the culture of kiwifruit in liquid medium except with respect to phosphate which decreased significantly toward the end of the culture period. Sucrose, and the glucose resulting from the hydrolysis of the former, were taken up by the kiwi explants throughout the whole culture period. GA₃ absorption by the kiwi explants occurred gradually throughout the subculture, although 67% of this initially added plant growth regulator remained in the culture medium at the end of the 35-d culture period.     

Diverse Secondary Metabolites Produced by Marine‐Derived Fungus Nigrospora sp. MA75 on Various Culture Media

Bioassay‐guided isolation of a fungal strain Nigrospora sp. MA75, an endophytic fungus obtained from the marine semi‐mangrove plant Pongamia pinnata, which was fermented on three different culture media, resulted in the isolation and identification of seven known compounds, 2, 3 , and 5 – 9 , from a medium containing 3.5% NaCl, while a new compound, 2,3‐didehydro‐19α‐hydroxy‐14‐epicochlioquinone B ( 10 ) was obtained from the medium containing 3.5% NaI. In addition, two new griseofulvin derivatives, 6‐O‐desmethyldechlorogriseofulvin ( 1 ) and 6′‐hydroxygriseofulvin ( 4 ), were isolated and identified from the rice solid medium. Dechlorogriseofulvin ( 2 ) and griseofulvin ( 3 ) were the major components in fermentation extracts of all these culture media, while compounds 1 and 4, 5 and 6 , and 10 were only present in the extract of respective culture medium. The structures of these compounds were elucidated by detailed spectroscopic analysis, and the absolute configuration of 1 was determined by CD measurement. Compounds 9 and 10 exhibited antibacterial activities toward five tested bacterial strains, while compounds 5, 6 , and 8 selectively inhibited MRSA, E. coli, and S. epidermidis, and compound 3 showed moderate activity against V. mali and S. solani. Moreover, compound 10 potently inhibited the growth of MCF‐7, SW1990, and SMMC7721 tumor cell lines with IC₅₀ values of 4, 5, and 7 μg/ml, respectively.     

Study of in situ 1-butanol pervaporation from A-B-E fermentation using a PDMS composite membrane: validity of solution-diffusion model for pervaporative A-B-E fermentation

In this study, the application of a new polydimethylsiloxane (PDMS)/dual support composite membrane was investigated by incorporating the pervaporation process into the A-B-E (acetone-butanol-ethanol) fermentation. The performance of the A-B-E fermentation using the integrated pervaporation/fermentation process showed higher biomass concentrations and higher glucose consumption rates than those of the A-B-E fermentation without pervaporation. The performance of the membrane separation was studied during the separation of 1-butanol from three different 1-butanol solutions: binary, model, and fermentation culture solutions. The solution-diffusion model, specifically the mass transfer equation based on Fick's First Law, was shown to be applicable to the undefined A-B-E fermentation culture solutions. A quantitative comparison of 1-butanol separation from the three different solutions was made by calculating overall mass transfer coefficients of 1-butanol. It was found that the overall mass transfer coefficients during the separation of binary, model, and fermentation culture solutions were 1.50, 1.26, and 1.08 mm/h, respectively.     

Plant regeneration from isolated microspore cultures of Chinese cabbage (Brassica campestris spp. pekinensis)

Isolated microspores of Chinese cabbage (Brassica campestris ssp. pekinensis) were incubated in modified NN medium containing 10% sucrose in darkness at 33°C for one day followed by culture at 25°C. After 14 days of culture, microspores developed into embryos ranging from globular to cotyledonary stage. Plants were regenerated after transfer of embryos to medium containing 3% sucrose and no plant growth regulators.Abbreviations NN Nitsch and Nitsch - MS Murashige and Skoog - NAA naphthaleneacetic acid - BA 6-benzylaminopurine     

Induction of intratumoral tumor necrosis factor by a synthetic lipid A analog, ONO-4007, with less tolerance in repeated administration and its implication in potent antitumor effects with low toxicity

To evaluate the anti-tumor characteristics of ONO-4007, a synthetic analog of lipid A, the authors examined its acute toxicity and anti-tumor activity in a mouse MM46 mammary tumor system in comparison with LA-15-PP, an E. coli-type synthetic lipid A and LPS. Systemic and local (tumor site) induction of tumor necrosis factor (TNF) by a single i.v. shot of ONO-4007 and LA-15-PP correlated with manifestation of their toxicity, showing that ONO-4007 is 100-fold less effective than LA-15-PP. However, a protocol of repeated administration (3 shots twice a week) exhibited about 10 times more therapeutic potency of ONO-4007 for cancer therapy than expected in the above experiments. In a dose inducing submaximal systemic and intratumoral TNF production, repeated injections (twice a week) of ONO-4007 (10 mg/kg), LA-15-PP (0.1 mg/kg) and LPS (0.1 mg/kg) commonly generated a tolerant state in the systemic response (serum and liver) to subsequent stimulation. The intratumoral response was retained with this repeated administration of ONO-4007, but was not with LA-15-PP or LPS. TIM (tumor-infiltrating macrophages) isolated from mice pre-injected with ONO-4007 and LA-15-PP were found to lose their response to both substances, but the response was rapidly recovered until 72 h after injection and virtually no difference was observed in their response to either drug. The in vitro treatment of naive TIM with ONO-4007 or LA-15-PP for 2 h depressed the response to both substances and the depression continued for 72 h even in culture with fresh medium. The relatively high efficacy of ONO-4007 in cancer therapy likely depends on the retraction of the tolerant state, especially at the tumor site where the response to ONO-4007 is recovered much more efficiently than that to lipid A. While constant recruitment of macrophages to tumor tissue might be involved in the difference of tolerance recovery between this region and others, selective response to ONO-4007 may not be explained simply by the sensitivity of recruited TIM. Pharmacokinetical experiments revealed that repeated injections of LA-15-PP enhanced its clearance from blood circulation, while the clearance of ONO-4007 was stable after repeated injections. Thus, pharmacokinetical properties of ONO-4007 may also possibly be implicated in this event.     

Application of bioreactors for large-scale micropropagation systems of plants

Summary The application of bioreactor culture techniques for plant micropropagation is regarded as one of the ways to reduce production cost by scaling-up and automation. Recent experiments are restricted to a small number of species that, however, demonstrate the feasibility of this technology. Periodic immersion liquid culture using ebb and flood system and column-type bubble bioreactors equipped with a raft support system to maintain plant tissues at the air and liquid interface were found to be suitable for micropropagation of plants via the organogenic pathway. Balloon-type bubble bioreactors proved to be fit for micropropagation via somatic embryogenesis with less shear stress on cultured cells. Several cultivars of Lilium were successfully propagated using a two-stage culture method in one bioreactor. A large number of small-scale segments were cultured for 4 wk with periodic immersion liquid culture to induce multiple bulblets from each segment, then the bulblet induction medium was changed into bulblet growth medium by employing a submerged liquid bioreactor system. This culture method resulted in a nearly 10-fold increase in bulblet growth compared to conventional culture with solid medium. About 20 000 cuttings of virus-free potato could be obtained from 120 singlenode explants in a 20-liter balloon-type bubble bioreactor after 8 wk of culture. The percentage of ex vitro survival and root induction of the cuttings was more than 95%. Other successful results were obtained from the micropropagation and transplant production of chrysanthemum, sweetpotato, Chinese foxglove. Propagation systems via somatic embryogenesis in Acanthopanax koreanum and thornless Aralia elata were established using a liquid suspension of embryogenic determined cells. More than 500 000 somatic embryos in different stages were harvested from a 10-liter balloon-type bubble bioreactor after a 6-wk culture. Further development of these embryos in solid medium and eventually in the field was successful. The bioreactor system could reduce initial and operational cost for micropropagation, but further development of sophisticated technology might be needed to apply this system to plant micropropagation industries.     

Somatic embryogenesis from ovaries of sweet orange cv. Tobias

Callogenesis, somatic embryogenesis, and regeneration were obtained from tissues of unfertilized ovaries of sweet orange (Citrus sinensis Osbeck.) cv. Tobias. The influence of two modified basal media, woody plant medium (WPM) and N6 medium, to induce callus formation from pistils was determined. Overall, high frequencies of callogenesis were observed when either medium was used. However, initial culture of explants in WPM medium followed by transfer of callus to N6 medium resulted in higher frequency of callus induction (of 2.30 callus per explant that were larger than 0.5 cm in size), and of subsequent development of embryogenic callus (10%). A total of 125 somatic embryos were obtained. After 6 months of culture, 72% of somatic embryos germinated into plantlets. These plantlets were subsequently micrografted in vitro, and then acclimatized. Ploidy of these plants were determined using flow cytometry and TRAPS molecular markers were used to confirm their maternal origin.     

Plant regeneration from leaf protoplasts of evening primrose (Oenothera hookeri)

A protocol is presented for regenerating plants from leaf protoplasts of Oenothera. The method uses (1) embedding of isolated protoplasts at high cell densities in thin alginate layers, (2) initial culture in B5 medium containing 3 mg l^–1 α-naphthaleneacetic acid (NAA) and 1 mg l^-1 6-benzylaminopurine (BAP), (3) reduction of the osmotic pressure of the culture medium at early stages of culture and (4) plating of microcolonies recovered from the alginate onto solid B5 medium with 3 mg l^–1 NAA and 1 mg l^–1 BAP. The shortest time required from protoplast isolation to the appearance of shoot initials was 7 weeks. The efficiency of the procedure for protoplast to cell line formation is high (about 80%). Received: 17 February 1997 / Revision received: 6 November 1997 / Accepted: 15 November 1997