Development and application of RAPD-SCAR markers to identify intra-species hybrids of industrial Saccharomyces cerevisiae

To overcome the drawbacks of protoplast fusion in industrial breeding, strain-specific molecular markers were applied to select hybrids of industrial Saccharomyces cerevisiae strains. Random Amplified Polymorphic DNA (RAPD) analysis was used to generate strain-specific RAPD markers for two industrial yeast strains, Z8 and Z9. For industrial and technical controls, two RAPD markers with non-coding regions were converted into stable Sequence Characterized Amplified Region (SCAR) markers. Hybrids of Z8 and Z9 were obtained by protoplast fusion in combination with SCAR markers and were found to increase ethanol production by 4.3–8.1%. Results suggested that protoplast fusion could be combined with RAPD-SCAR molecular markers and applied in industrial breeding instead of auxotrophic markers.     

Isolation of cytoplasts from Satsuma mandarin (Citrus unshiu Marc.) and production of alloplasmic hybrid calluses via cytoplast–protoplast fusion

Cytoplasm of Satsuma mandarin (Citrus unshiu Marc.) is known to influence seedlessness. Transfer of cytoplasm to a seedy cultivar could possibly lead to the production of seedless citrus fruits. In the present paper cytoplasts were isolated from cell suspension-derived protoplasts of Satsuma mandarin via ultra-centrifugation in a discontinuous gradient. No nucleus could be detected in the cytoplasts by DAPI (4′, 6-diamidino-2-phenylindole) staining compared with normal protoplasts. The cytoplasts, with high viability and small size, did not divide during solid embedding culture. Cytoplasts of Satsuma mandarin were electrically fused with embryogenic protoplasts of Murcott tangor (C. reticulata × C. sinensis), which led to regeneration of several cell lines. Flow cytometry (FCM) indicated that the cell lines were diploids. Simple sequence repeats (SSR) and cleaved amplified polymorphism sequence (CAPS) showed that the cell lines got their nuclear DNA from the protoplast parent, whereas the cytoplast parent donated the mtDNA, confirming transfer of mtDNA from Satsuma mandarin into Murcott tangor via cytoplast–protoplast fusion though no polymorphism was detected in chloroplast DNA between the fusion partners. This is the first report on isolation and characterization of cytoplasts, together with cytoplast–protoplast fusion in Citrus, which has a potential for citrus cultivar improvement involving cytoplasm transfer via cytoplast–protoplast fusion.     

Cell Wall Regeneration in Bangia atropurpurea (Rhodophyta) Protoplasts Observed Using a Mannan-Specific Carbohydrate-Binding Module

The cell wall of the red alga Bangia atropurpurea is composed of three unique polysaccharides (β-1,4-mannan, β-1,3-xylan, and porphyran), similar to that in Porphyra. In this study, we visualized β-mannan in the regenerating cell walls of B. atropurpurea protoplasts by using a fusion protein of a carbohydrate-binding module (CBM) and green fluorescent protein (GFP). A mannan-binding family 27 CBM (CBM27) of β-1,4-mannanase (Man5C) from Vibrio sp. strain MA-138 was fused to GFP, and the resultant fusion protein (GFP–CBM27) was expressed in Escherichia coli. Native affinity gel electrophoresis revealed that GFP–CBM27 maintained its binding ability to soluble β-mannans, while normal GFP could not bind to β-mannans. Protoplasts were isolated from the fronds of B. atropurpurea by using three kinds of bacterial enzymes. The GFP–CBM27 was mixed with protoplasts from different growth stages, and the process of cell wall regeneration was observed by fluorescence microscopy. Some protoplasts began to excrete β-mannan at certain areas of their cell surface after 12 h of culture. As the protoplast culture progressed, β-mannans were spread on their entire cell surfaces. The percentages of protoplasts bound to GFP–CBM27 were 3%, 12%, 17%, 29%, and 25% after 12, 24, 36, 48, and 60 h of culture, respectively. Although GFP–CBM27 bound to cells at the initial growth stages, its binding to the mature fronds was not confirmed definitely. This is the first report on the visualization of β-mannan in regenerating algal cell walls by using a fluorescence-labeled CBM.     

Induction of fast-growing and morphologically different strains through intergeneric protoplast fusions of Ulva and Enteromorpha (Ulvales,Chlorophyta)

Isolated protoplasts of Ulva pertusa and Enteromorpha prolifera were electrically fused. Treatment of protoplasts in 1% protease for 15–20 min prior to fusion enhanced fusion ability. Protoplasts from each fusion partner were mixed together in 1:1 ratio in low conductivity electrofusion solution at a density of 1 × 10⁵ cells ml⁻¹ before subjecting them to electrofusion. The protoplasts were aligned in AC field (1MHz, 25 V for 10–15 s) and subsequently fused by a high intensity single DC pulse of 250 V for 25 μs duration. Fusion buffer supplemented with 1 mM calcium and 1 mM magnesium yielded optimum fusion frequencies (about 18–24%). Entrapment of fusion treated cells inside agarose/agar plate facilitated marking and regeneration of fusion products. The regeneration patterns of fused protoplasts were similar to normal (unfused) protoplast development. Most of the regenerated plants from fusion products had a thallus similar to either U. pertusa type or E. prolifera type. Although some of the plants of the former were morphologically similar to U. pertusa, but most had a higher growth rate (1.9 to 1.5 times) than U. pertusa. Furthermore the thallus of some plants had a characteristic irregular and dentate margin, which was never observed in the parental type.     

Optimization of protoplast yields from the red algae <Emphasis Type="Italic">Gracilaria dura</Emphasis> (C. Agardh) J. Agardh and G. <Emphasis Type="Italic">verrucosa</Emphasis> (Huds.) Papenfuss

This study reports on the optimization of protoplast yield from two important tropical agarophytes Gracilaria dura and Gracilaria verrucosa using different cell-wall-degrading enzymes obtained from commercial sources. The conditions for achieving the highest protoplast yield was investigated by optimizing key parameters such as enzyme combinations and their concentrations, duration of enzyme treatment, enzyme pH, mannitol concentration, and temperature. The significance of each key parameter was also further validated using the statistical central composite design. The enzyme composition with 4% cellulase Onozuka R-10, 2% macerozyme R-10, 0.5% pectolyase, and 100 U agarase, 0.4 M mannitol in seawater (30‰) adjusted to pH 7.5 produced the highest protoplast yields of 3.7 ± 0.7 × 10⁶ cells g⁻¹ fresh wt for G. dura and 1.2 ± 0.78 × 10⁶ cells g⁻¹ fresh wt for G. verrucosa when incubated at 25°C for 4–6 h duration. The young growing tips maximally released the protoplasts having a size of 7–15 μm in G. dura and 15–25 μm in G. verrucosa, mostly from epidermal and upper cortical regions. A few large-size protoplasts of 25–35 μm, presumably from cortical region, were also observed in G. verrucosa.     

Cloned calves produced by nuclear transfer from cultured cumulus cells

Short-term cultured cumulus cell lines (1-5BCC) derived from 5 individual cows were used in nuclear transfer (NT) and 1188 enucleated bovine oocytes matured in vitro were used as nuclear recipients. A total of 931 (78.4%) cloned embryos were reconstructed, of which 763 (82%) cleaved, 627 (67.3%) developed to 8-cell stage, and 275 (29.5%) reached blastocyst stage. The average cell number of blastocysts was 124±24.5 (n=20). In this study, the effects of donor cell sources, serum starvation of donor cells, time interval from fusion to activation (IFA) were also tested on cloning efficiency. These results showed that blastocyst rates of embryos reconstructed from 5 different individuals cells were significantly different among them (14.1%, 45.2%, 27.3%, 34.3%, vs 1.5%, P<0.05); that serum starvation of donor cells had no effect on blastocyst development rate of NT embryos (47.1% vs 44.4%, P>0.05); and that blastocyst rate (20.3%) of the group with fusion/activation interval of 2–3 h, was significantly lower than that of the 3–6 h groups (31.0%), while not significantly different among 3–4 h (P < 0.05), 4–5 h, and 5–6 h groups (P≥0.05). Sixty-three thawed NT blastocysts were transferred to 31 recipient cows, of which 4 pregnancies were established and two cloned calves were given birth. These results indicate that serum starvation of cumulus cells is not a key factor for successful bovine cloning, while IFA treatment and sources of donor cells have effects on cloning efficiency.     

Effect of enzyme concentrations on protoplast isolation and protoplast culture of <Emphasis Type="Italic">Spathiphyllum</Emphasis> and <Emphasis Type="Italic">Anthurium</Emphasis>

Vital protoplasts from Spathiphyllum wallisii ‘Alain’ and Anthurium scherzerianum ‘238’ were isolated from both somatic embryos and leaves. The highest yields were obtained when 1.5% cellulase, 0.5% macerase and 0.5% driselase were used for Spathiphyllum wallisii leaves and 0.5% cellulase, 0.3% macerase and 0.5% driselase for Anthurium scherzerianum embryos. About 1 × 10⁶ protoplasts g⁻¹ and 1 × 10⁵ protoplasts g⁻¹ could be isolated from leaves and embryos, respectively. For protoplast fusion Spathiphyllum wallisii ‘Alain’ and Anthurium scherzerianum ‘238’ were mixed in a 1:1 ratio in a fusion solution containing 1 mM CaCl₂·2H₂O, 1 mM MES and 0.5 M mannitol. Fusion was performed by protoplast alignment under 500 V cm⁻¹ alternating current for 60 s and subsequent generation of two pulses of 4500 V cm⁻¹ direct current during 50 μs. Development until colony stage was achieved using agarose beads for protoplast culture.     

Efficient regeneration of plantlets from callus and mesophyll derived protoplasts of <Emphasis Type="Italic">Robinia pseudoacacia</Emphasis> L.

A protocol for plant regeneration from mesophyll and callus protoplasts of Robinia pseudoacacia L. was developed. For leaves from in vitro raised shoots, an enzyme combination of 2.0% cellulose and 0.3% macerozyme for a digestion period of 20 h resulted in the best yield of protoplasts (9.45 × 10⁵ protoplast/g fresh weight). Mesophyll-derived protoplasts started cell wall regeneration within 24 h of being embedded in Nagata and Takebe (NT) medium supplemented with 5 μM NAA and 1 μM BAP followed by the first cell division on day three of culture and micro-colony (32 cells) formation within day 7–10 in the same medium. However, using callus as the starting material, a combination of 2.0% cellulose and 1.0% macerozyme for a digestion period of 24 h gave the highest protoplast yield (3.2 × 10⁵ protoplast/g fresh weight). Cell wall regeneration in callus-derived protoplasts started within 24 h followed by the first cell division on the day three (96 h) and the appearance of microcolonies of more than 32 cells by the end of first week (144 h) of culture on solid WPM medium supplemented with 5 μM NAA and 1 μM BAP. Microcalli were visible to the naked eye after 45 days on solid WPM medium. Proliferation of macro-calli was successfully accomplished on solid Murashige and Skoog (MS) medium with 5 μM NAA and 5 μM BAP. Both mesophyll and callus protoplast-derived calli produced shoots on MS medium with 0.5 μM NAA and 1 μM BAP within 25–30 days and multiplied on MS medium with 1.25 μM BAP. Excised microshoots were dipped in 1–2 ml of 2.0 μM IBA for 24 h under dark aseptic conditions and transferred to double sterilized sand for rooting. The flasks containing sand were inoculated with Rhizobium for in vitro nodulation. Forty-five plants transferred to pots in the glasshouse established well.     

Expression of green-fluorescent protein gene in sweet potato tissues

Green-fluorescent protein (GFP) gene expression, transient and stable after electroporation and particle bombardment, was analyzed in tissues of sweet potato cv.Beauregard. Leaf and petiole tissues were used for protoplast isolation and electroporation. After 48 h, approximately 25–30% of electroporated mesophyll cell protoplasts regenerated cell walls, and of these, 3% expressed GFP. Stable expression of GFP after four weeks of culture was observed in 1.0% of the initial GFP positive cells. In a separate experiment, we observed 600–700 loci expressing GFP 48 h after bombarding leaf tissue or embryogenic calli, and stable GFP-expressing sectors were seen in leaf-derived embryogenic calli after four weeks of protoplast culture without selection. These results demonstrate GFP gene expression in sweet potato tissues. Screening for GFP gene expression may prove useful to improve transformation efficiency and to facilitate detection of transformed sweet potato plants.     

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     

Transformation of sweet potato tissues with green-fluorescent protein gene

Summary The expression of the green-fluorescent protein (GFP) gene from Aequorea victoria (jellyfish) was analyzed by transient and stable expression in sweet potato Ipomoea batatas L. (Lam.) ev. Beauregard tissues by electroporation and particle bombardment. Leaf and petiole segments from in vitro-raised young plantlets were used for protoplast isolation and electroporation. Embyrogenic callus was also produced from leaf segments for particle bombardment experiments. A buffer solution containing 1×10⁶ protoplasts ml⁻¹ was mixed with plasmid DNA containing the GFP gene, and electroporated at 375 V cm⁻¹. Approximately 25–30% of electroporated mesophyll cell protoplasts subsequently cultured in KM8P medium regenerated cell walls after 48 h. Of these, 3% emitted bright green fluorescence when exposed to UV-blue light at 395 nm. Transformed cells continued to grow after embedding in KM8P medium solidifed with 1.2% SeaPlaque agarose. Stable expression of GFP was observed after 4 wk of culture in approximately 1.0% of the initial GFP positive cells (27.5 GFP positive micro callases out of 3024 cells which transiently expressed GFP 48 h after electroporation). In a separate experiment, 600–700 bright green spots were observed per plate 48 h after bombarding leaf segments or embryogenic cellus. In bombarded cultures, several stable GEP-expressing sectors were observed in leafderived embryogenic callus grown without selection for 4 wk. These results show that GFP gene expression can occur in various sweet potato tissues, and that it may be a useful sereenable marker to improve transformation efficiency and obtain transgenic sweet potato plants.     

Plant regeneration via somatic embryogenesis, and transient gene expression in sweet potato protoplasts

A method for regenerating plants from petiole protoplasts of the in vitro-raised sweet potato cultivar Jewel is described. Protoplast yields of 3.0–5.0×10⁶ were obtained following 4–6 h digestion of 1- to 2-cm petioles (1 g fresh weight) with 1% Cellulase-R10, 2% Macerozyme-R10, and 0.3% Pectolyase Y-23 in a washing solution with 9% mannitol. A plating density of 10⁵ protoplasts/ml was optimal for subsequent division. An initial division frequency of 12–15% was obtained in liquid or agarose-solidified KP8 culture medium supplemented with 2,4-dichlorophenoxyacetic acid (2,4-D) (0.9 μm), and zeatin (2.3 μm). Colonies consisting of 100–200 cells were formed after 4 weeks in the dark at 24±2°C. The frequency of colony formation was improved by the gradual addition of fresh liquid KP8 medium of lower osmoticum. Protocalli (1–2 mm in diameter) were formed after an additional 4–6 weeks under continuous illumination and regular dilution with fresh culture medium. Morphogenic callus formed globular and heart-shaped embryos that developed into cotyledon stage embryos, following transfer of calli onto medium containing 2,4-D (11.3 μm) and benzylaminopurine (2.2 μm). Subsequently, embryo conversion to plantlets was obtained on basal medium with 2% sucrose and 3.5 μm gibberellic acid. Regenerated plantlets were successfully transplanted in soil. Mature plants appeared phenotypically normal. The same petiole protoplast populations showed transient expression of the gusA gene introduced using electroporation. Received: 10 October 1997 / Revision received: 10 February 1998 / Accepted: 2 March 1998     

Light-Enhanced Uptake of Metabolites in Mesophyll Protoplasts: Evidence for a Novel Pyruvate Transport System

3 ) and sorghum (C₄) leaves for the measurements of osmotic volume change and metabolite uptake. We first investigated whether the silicone oil layer filtering centrifugation method could be applied to the protoplasts. The density of the silicone oil was optimized (ρ =1.026) and 0.5M betaine was chosen as an osmoticum in the protoplast suspending medium. By using [¹⁴C] sorbitol and [¹⁴C] inulin as the marker of the medium carried over into the pellet, protoplast osmotic or internal volume was estimated to be 200–300 μl (mg Chl)⁻¹, with the medium space in the pellet of 8–15 μl (mg Chl)⁻¹. Lowering of the osmotic pressure of the medium induced protoplast swelling as expected. Light also induced swelling. Using this system, we could detect light-enhanced uptake of ascorbate, glutamate and pyruvate in both barley and sorghum protoplasts. Pyruvate uptake was far higher in barley than in sorghum and inhibited by various inhibitors, showed saturation kinetics and, therefore, seemed to be mediated by a translocator protein. Received 10 August 1999/ Accepted in revised form 6 December 1999     

Oligosaccharides induce changes in protein patterns of regenerating spruce protoplasts

Galactoglucomannan oligosaccharides (GGMOs, d.p. 4–8 and fractions d.p. 3, 4, 5, 6–7), used in culture media for spruce protoplasts derived from callus cells showed a pleiotropic effect. They influenced both, quality and quantity of extracellular proteins in regenerating protoplasts. GGMOs d.p. 4, 5 at pH 6.0 and the mixture of d.p. 4–8 (pH 3.8 and 6.0) after 48 h of culture increased the amount of extra- and intracellular proteins and the viability of protoplasts. The most significant effect on protoplasts viability in the presence of GGMOs d.p. 4–8 without the growth hormone supplementation at pH 3.8, and with lower efficiency in the presence of NAA (1 mg/l) has been observed. The most significant differences were observed in the molecular mass intervals Mr∼17–21 kDa, 25–30 kDa, and 45–60 kDa. After 24 h of culture extracellular acid proteins with Mr∼30; 41; 68; and 90 in media supplemented with GGMOs d.p. 3, 4, 5, 6–7 (pH 6.0) with or without NAA were identified to belong to the group of β-1,3-glucanases. Extracellular proteins p27.5; 30; 41; 50; 52 and 90 exhibited chitinase activity after 24 h of protoplast cultivation. GGMOs probably fulfil a protective role in this process of spruce protoplast regeneration.     

Development and Evaluation of Hydrophilic Colloid Matrix of Famotidine Tablets

The objective of the present study was to develop a once-daily sustained-release (SR) matrix tablet of famotidine. Nine different formulations (F1–F9) were prepared by direct compression method using Avicel PH101 as filler/binder in the range of 41–27% in F1–F3, 18–22% in F4–F7, and 16–18% in F8–F9 and hydroxypropyl methylcellulose (4,000 cps) as hydrophilic matrix was used in F1–F3 from 19% to 30%, around 40% in F4–F7, and 42–45% in F8–F9. Talc and Aerosil were added in the ratio of 0.7–1.2%. The tablets were subjected to various physical parameters including weight variation test, hardness, thickness, diameter, friability, and in vitro release studies. Assay was also performed according to the USP 30 NF 25 procedure. The results of the physical parameters and assay were found to be within the acceptable range. In vitro dissolution results indicated that formulation F4–F7, having around 40% of rate control polymer, produced a SR pattern throughout 24 h. F1–F3 showed drug release at a faster rate, while F8–F9 released much slower, i.e., <80% in 24 h. Model-dependent and model-independent methods were used for data analysis and the best results were observed for F4 in zero order (r ² = 0.984) and F6 in Korsmeyer and Higuchi (r ² = 0.992 and 0.988). The parameter n indicated anomalous diffusion, while β in Weibull showed a parabolic curve with higher initial slope. The f ₂ similarity test was performed taking F4 as a reference formulation. Only the F5–F7 formulations were similar to the reference formulation F4. The mean dissolution time was around 10 h for the successful formulation.     

In vitro induction, regeneration and analysis of autotetraploids derived from protoplasts and callus treated with colchicine in Citrus

In the present paper attempts were made to induce chromosome doubling of ‘Meiwa’ kumquat (Fortunella crassifolia) protoplasts and ‘Frost’ navel orange (Citrus sinensis Osbeck) embryogenic callus via colchicine treatment. Colchicine decreased protoplast viability, delayed protoplast division and inhibited callus growth, indicating presence of toxicity to cells. Cell lines established from ‘Meiwa’ protoplasts treated with 0.01 and 0.1% colchicine for 8, 16 and 24 h at each concentration showed different responses when they were cultured on embryoid-induction medium. Flow cytometry (FCM) demonstrated that tetraploids were detected in cell lines and embryoids from all of the treatments, with the highest frequency being 19.23%. As for ‘Frost’, tetraploid cells were only detected when the callus was treated with 0.1% colchicine for either 4 or 8 days, from which plantlets were regenerated. FCM and chromosome counting confirmed them as true tetraploids. The diploid cells were more active in mitotic division during a 12-day culture and smaller in size than their tetraploid counterpart. Potential applications of the novel tetraploid germplasms obtained through in vitro chromosome doubling to citrus cultivar improvement are discussed.     

Chemical and genetic characterization of calli derived from somatic hybridization between tansy (Tanacetum vulgare L.) and pyrethrum (Tanacetum cinerariifolium (Trevir.) Schultz-Bip.)

 Pyrethrum (Tanacetum cinerariifolium (Trevir.) Schultz-Bip.) produces environmentally benign pesticides, the pyrethrins, and tansy (Tanacetum vulgare L.) lower terpenes of variable biological effectiveness. As an approach to improve the oil content and composition of tansy for enhanced biological activity, a somatic hybridization technique between tansy and pyrethrum was established. About 1×10⁶ of leaf-mesophyll protoplasts of both species were mixed and fused with a solution containing 15% polyethylene glycol. Light-green and yellowish calli developed from the fusion experiments. The fusion-derived calli grew vigorously on MS medium supplemented with 6.4 mg l^-1 of BAP, 0.8 mg l^-1 of NAA, and 30–40 g l^-1 of glucose. Nuclear DNA content, RAPD patterns, and volatile compounds were analyzed to determine the hybridity of the calli. The nuclear DNA content of the tansy and pyrethrum genotypes, and the protoplast-derived calli of tansy were 6.41, 7.39, 13.84, and 8.11 pg, respectively. The nuclear DNA content of individual calli derived from the protoplast fusion between tansy +tansy ranged from 8.84 (F43A) to 19.59 pg (F43C) while those of the tansy+pyrethrum fusions were 10.66 (F46A) and 31.87 pg (F46B). Using four 10-mer primers a total of 56 RAPD-PCR fragments were produced. The distance matrices of fragments were calculated by average linkage cluster analysis. Two visually separated clusters were observed. One cluster consisted of the two tansy genotypes and the fusion-derived callus F43A; the other consisted of pyrethrum and fusion-derived calli F46B and F46C. Volatile compounds, such as decadienal, artedouglasia oxide, heptadecane, syringaldehyde and coniferyl alcohol, analyzed by gas chromatography mass spectrometry, were found only in the protoplast fusion-derived calli F43A and F46B. Several less volatile compounds were also detected only in fusion calli. Hexadecanoic and linoleic acids were common to fusion-derived calli and tansy, and one unknown compound to fusion-derived calli and pyrethrum. Pyrethrins I and II were detected from pyrethrum, but not from the fusion-derived calli. The additive nuclear DNA content of protoplast fusion-derived calli and the results of the RAPDs suggest that interspecific fusions had occurred. The small number of volatile compounds detected from both the fusion calli and from the donor species indicates that the unorganized callus tissue is unable to produce tissue-specific volatile compounds. Received: 4 August 1998 / Accepted: 30 September 1998     

Isolation,callus formation and plantlet regeneration from mesophyll protoplasts of <Emphasis Type="Italic">Tylophora indica</Emphasis> (Burm. f.) Merrill: an important medicinal plant

Protoplast culture and plant regeneration of an important medicinal plant Tylophora indica were achieved through callus regeneration. Protoplasts were isolated from leaf mesophyll cells and cultured at a density of 5 × 10⁵ protoplasts per gram fresh weight, which is required for the highest frequency of protoplast division (33.7%) and plating efficiency (9.3%). The first division was observed 2 d after plating and the second division after 4 d. Culture medium consists of Murashige and Skoog (MS) liquid medium with 4 μM 2,4-D, 0.4 M mannitol and 3% (w/v) sucrose with pH adjusted to 5.8. After 45 d of culture at 25°C in the dark, protoplasts formed colonies consisting of about 100 cells. The protoplast-derived microcalli were visible to the naked eye within 60 d of culture and reached a size of 0.2–0.4 mm in diameter after 90 d. Calli of 0.2–0.4-mm size were transferred to MS medium supplemented with 2,4-D (4 μM), 3% (w/v) sucrose and 0.8% (w/v) agar, formed friable organogenic calli (7-8 mm size) after 8 wk under incubation in normal light period supplemented with 200 μmol m⁻² S⁻¹ of day light fluorescent illumination. The calli were transferred to MS medium supplemented with thidiazuron (TDZ) (1–7 μM) and naphthalene acetic acid (NAA) (0.2–0.4 μM) for regeneration. The calli developed shoot buds after 3–4 wk, and the frequencies of calli-forming shoots varied from 5% to 44%. Optimum shoot regeneration occurred on MS medium supplemented with 5 μM TDZ and 0.4 μM NAA. On this medium, 44% cultures responded with an average number of 12 shoots per callus. Whole plants were recovered following rooting of shoots in 1/2 MS medium supplemented with 3 μM indole 3-butyric acid.     

Screening and breeding of high taxol producing fungi by genome shuffling

To apply the fundamental principles of genome shuffling in breeding of taxol-producing fungi, Nodulisporium sylviform was used as starting strain in this work. The procedures of protoplast fusion and genome shuffling were studied. Three hereditarily stable strains with high taxol production were obtained by four cycles of genome shuffling. The qualitative and quantitative analysis of taxol produced was confirmed using thin-layer chromatography (TLC), high performance liquid chromatography (HPLC) and LC-MS. A high taxol producing fungus, Nodulisporium sylviform F4-26, was obtained, which produced 516.37 μg/L taxol. This value is 64.41% higher than that of the starting strain NCEU-1 and 31.52%–44.72% higher than that of the parent strains.     

Bioremoval of hexavalent chromium from water by a salt tolerant bacterium, Exiguobacterium sp. GS1

Pollution of terrestrial surfaces and aquatic systems by hexavalent chromium, Cr(VI), is a worldwide public health problem. A chromium resistant bacterial isolate identified as Exiguobacterium sp. GS1 by 16S rRNA gene sequencing displayed high rate of removal of Cr(VI) from water. Exiguobacterium sp. GS1 is 99% identical to Exiguobacterium acetylicum. The isolate significantly removed Cr(VI) at both high and low concentrations (1–200 μg mL⁻¹) within 12 h. The Michaelis–Menten K _m and V _max for Cr(VI) bioremoval were calculated to be 141.92 μg mL⁻¹ and 13.22 μg mL⁻¹ h⁻¹, respectively. Growth of Exiguobacterium sp. GS1 was indifferent at 1–75 μg mL⁻¹ Cr(VI) in 12 h. At initial concentration of 8,000 μg L⁻¹, Exiguobacterium sp. GS1 displayed rapid bioremoval of Cr(VI) with over 50% bioremoval in 3 h and 91% bioremoval in 8 h. Kinetic analysis of Cr(VI) bioremoval rate revealed zero-order in 8 h. Exiguobacterium sp. GS1 grew and significantly reduced Cr(VI) in cultures containing 1–9% salt indicating high salt tolerance. Similarly the isolate substantially reduced Cr(VI) over a wide range of temperature (18–45  °C) and initial pH (6.0–9.0). The T _opt and initial pH_opt were 35–40  °C and 7–8, respectively. Exiguobacterium sp. GS1 displayed a great potential for bioremediation of Cr(VI) in diverse complex environments.