Medium,container and genotype all influence in vitro cold storage of apple germplasm

The goal of this study was to evaluate the in vitro storage of apple germplasm by screening a range of genotypes followed by more comprehensive testing of multiple parameters on two genotypes of differing species, Malus domestica cultivar Grushovka Vernenskaya and wild Malus sieversii selection TM-6. Stored plants were rated on a 6 point scale (0 low to 5 high) for plant appearance at 3 month intervals after storage at 4°C. Combinations of carbon source (sucrose and/or mannitol), nitrate nitrogen content (25, 50 or 100%) and plant growth regulators (ABA, BAP, IBA) were studied in three types of containers (tissue culture bags, test tubes or jars). An initial screen of 16 genotypes stored in tissue culture bags indicated that plantlets could be stored at 4°C for 9–14 months without subculture on standard 3% sucrose Murashige and Skoog (1962) (MS) medium with no plant growth regulators (PGRs). In subsequent in-depth studies on the two genotypes, ANOVA indicated highly significant interactions of medium, container and genotype. ‘Grushovka Vernenskaya’ shoots with no PGRs and 3% sucrose remained viable (ratings of ≥1) for 21 months of storage in bags. Storage on reduced nitrogen (MS with 25% nitrogen), PGRs, and 3% sucrose kept ‘Grushovka Vernenskaya’ shoot condition rated >2 at 21 months. Addition of 0.5 or 1 mg⁻¹ abscisic acid (ABA) also improved plant ratings at 21 months. The longest storage for ‘Grushovka Vernenskaya’ was 33–39 months with PGRs and 3% sucrose in either tubes or jars. Addition of abscisic acid (ABA) to the medium did not improve storage of plantlets in jars and tubes at 15 months. TM-6 stored best in tubes on 3% sucrose with PGRs or in jars on 2% mannitol and 2% sucrose. Overall it appears that cold storage of apple shoot cultures can be successful for 21 months in tissue culture bags with 25% MS nitrate nitrogen, 3% sucrose, and no PGRs or for 33 months in jars or tubes on MS with 3% sucrose and PGRs. Preliminary RAPD analysis found no significant differences between plants stored for 39 months and non-stored controls.     

The role of abscisic acid and plant growth regulators in tissue culture-induced rejuvenation of strawberry ex vitro

Plant growth regulators applied in vitro affected strawberry plant performance ex vitro for a period of up to 4 months. Benzyl-adenine and gibberellin enhanced juvenile characteristics; in general, more runners and monofoliolate leaves were produced, net photosynthesis was reduced, leaf diffusive resistance was increased and, on occasion, flowering was delayed. In contrast, abscisic acid and a gibberellin biosynthesis inhibitor, paclobutrazol, resulted in a more adult phenotype; specifically, flowering was earlier, net photosynthesis and leaf diffusive resistance rates were equal to those of adult plants, and fewer leaves were monofoliolate. Tissue culture-produced plants reacquire the adult phenotype earlier than seedlings mature. Abscisic acid application to seedlings also resulted in earlier and increased flowering.Endogenous abscisic acid concentrations were greater in adult plants and less in tissue culture and seedling plants at 3 and 7 weeks ex vitro, after germination or after adult runner propagation. No flowering occurred at 3 weeks in any propagation type and only runner-produced plants flowered at 7 weeks. At 15 weeks, no statistical difference in abscisic acid concentrations existed among propagation treatments and all propagation types flowered. The endogenous concentrations of abscisic acid in plants propagated by all three methods were much higher at three weeks compared to concentrations at 7 or 15 weeks.Abbreviations ABA +cis, trans-abscisic acid - BA benzyl-adenine - GC-SIM-MS combined gas chromatography-selected ion monitoring mass spectrometry - GA gibberellin A₃ - RS leaf diffusive resistance in sec cm^-1 - MS Murashige & Skoog medium devoid of plant growth regulators - Pn net photosynthesis in mol CO₂ fixed m^-2 sec^-1 - paclo paclobutrazol as 50WP - TC-plants plants produced from tissue culture - Tween20 polyoxyethylene-sorbitan monolaurate - RP runner plants - SDLG selfed seedlings     

In situ cryopreservation of human embryonic stem cells in gas-permeable membrane culture cassettes for high post-thaw yield and good manufacturing practice

Current strategies for marine pollution monitoring are based on the integration of chemical and biological techniques. The sea urchin embryo-larval bioassays are among the biological methods most widely used worldwide. Cryopreservation of early embryos of sea urchins could provide a useful tool to overcome one of the main limitations of such bioassays, the availability of high quality biological material all year round. The present study aimed to determine the suitability of several permeant (dimethyl sulfoxide, Me₂SO; propylene glycol, PG; and ethylene glycol, EG) and non-permeant (trehalose, TRE; polyvinylpyrrolidone, PVP) cryoprotectant agents (CPAs) and their combination, for the cryopreservation of eggs and embryos of the sea urchin Paracentrotus lividus. On the basis of the CPAs toxicity, PG and EG, in combination with PVP, seem to be most suitable for the cryopreservation of P. lividus eggs and embryos. Several freezing procedures were also assayed. The most successful freezing regime consisted on cooling from 4 to −12 °C at 1 °C/min, holding for 2 min for seeding, cooling to −20 °C at 0.5 °C/min, and then cooling to −35 °C at 1 °C/min. Maximum normal larvae percentages of 41.5% and 68.5%, and maximum larval growth values of 42.9% and 60.5%, were obtained for frozen fertilized eggs and frozen blastulae, respectively.     

Application of luminescence for quality evaluation of in vitro regenerated strawberry plants

The parameters of chlorophyll a fluorescence induction were measured: F_v/F_m, S_c/F_m, Rf_d and coefficient of L_d delayed luminescence decay kinetics, related with a course of primary photosynthesis reactions on leaves of strawberry plants, cultured in vitro by means of the micropropagation methods. Strawberry plants cv. Ananasowa from in vitro cultures in optimal condition show significantly higher values of luminescence parameters indicating better condition of plants of this variety in comparison with the variety Senga Sengana. After temperature lowering, however, these values were more reduced than for plants of Senga Sengana, which can be interpreted as higher susceptibility of this variety to chill. Addition of BAP caused disturbance of primary photosynthesis reactions rate, particularly in lower temperature. Auxin 2,4-D had no effect on the luminescence parameters in comparison with control cultures. Dehydration stress strongly diminished the values of measured parameters for Ananasowa variety what indicates the inhibition of primary photosynthesis reaction in leaves. The old culture of Senga Sengana variety showed higher tolerance on linuron in comparison with the new one.     

Invited review: Transformation of strawberry: The basis for translational genomics in Rosaceae

Summary Translational genomics is defined as the application of molecular-genetic principles derived from model systems to species of experimental or economic interest. The past 20 years of research in plant model systems such as Arabidopsis thaliana have relinquished vast amounts of information regarding gene function, the integration of genetic components into pathways, and the interrelationships between pathways to control form and function in plants and plant-products alike. At present, the challenge is to relate these paradigms to other species of economic or scientific interest. Apart from being an important and valuable crop, strawberry (Fragaria spp.) is a member of the Rosaceae, a plant family containing fruit, nut, ornamental and wood-bearing species. Strawberry is unique within the Rosaceae in that it is a rapidly growing herbaceous perennial with a small genome and the ability to thrive in a laboratory setting. Strawberry species may also be transformed and regenerated in a time scale of weeks or months instead of years. For these reasons, strawberry has been recognized as the translational genomics model for the Rosaceae family. This review summarizes and synthesizes the technical reports of strawberry regeneration and transformation, consolidating the large body of information regarding genetic modification of this important genus.     

Hormonal regulation of ripening in the strawberry,a non-climacteric fruit

Anthocyanin accumulation is one measure of ripening in the strawberry (Fragaria ananassa Duch.), a non-climacteric fruit. Neither aminoethoxyvinylglycine, an inhibitor of 1-aminocyclopropane carboxylic acid synthase, nor inhibitors of ethylene action (silver, norbornadiene) affected anthocyanin accumulation in ripening fruit. When the achenes were removed from one half of an unripe fruit there was an accelerated accumulation of anthocyanin and induction of phenylalanine ammonia lyase on the de-achened portion of the ripening fruit. These effects of achene removal could be prevented by the application of the synthetic auxins 1-naphthaleneacetic acid or 2,4-dichlorophenoxyacetic acid to the de-achened surface. The introduction of 1-naphthalene acetic acid into intact unripe strawberry fruit through the peduncle delayed their subsequent ripening, as measured by the accumulation of anthocyanin, loss of chlorophyll and decrease in firmness. These findings suggest that the decline in the concentration of auxin in the achenes as strawberry fruit mature modulates the rate of fruit ripening.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - AVG aminoethoxyvinylglycine - NAA 1-naphthaleneacetic acid - PA1 phenylalanine ammonia-lyase - POA phenoxyacetic acid - 2,4-D 2,4-dichlorophenoxyacetic acid     

In vitro cold storage of cork oak shoot cultures

Friable callus cultures were initiated from cotyledons and hypocotyls of Opuntia ficus-indica. Explants from cotyledons produced significantly more callus than those from hypocotyls. Optimum callus growth was observed on Murashige & Skoog medium supplemented with 0.9 μM 6-furfurylaminopurine, 2.3 μM 2,4-dichlorophenoxyacetic acid, 1.0 μM 4-amino 3,5,6-trichloropicolinic acid, 400 mg l^-1 casein hydrolysate and 3% sucrose. The same medium without agar was used for establishing cell suspensions. This revised version was published online in June 2006 with corrections to the Cover Date.     

Changes in gene expression during strawberry fruit ripening and their regulation by auxin

Changes in messenger RNA during the development of the strawberry (Fragaria ananassa Duch.), a non-climacteric fruit, were analysed by extracting total RNA and separating the in-vitro translated products by two-dimensional polyacrylamide gel electrophoresis. Alterations in numerous messenger RNAs accompanied fruit development between the immature green stage and the overripe stage, with prominent changes detected at or before the onset of ripening. A number of messenger RNAs undetectable in immature green fruit increased as the fruit matured and ripened. Others showed a marked decrease in advance of the ripening phase. A further group of messenger RNAs was prominent in immature and ripe fruit but absent just prior to the turning stage. Removing the achenes from a segment of the fruit accelerated anthocyanin accumulation in the de-achened portion and produced a pattern of translated polypeptides similar to normal ripe fruit. Application of the synthetic auxin 1-naphthaleneacetic acid to the de-achened receptacle produced a translation pattern similar to that in mature green fruit. These findings indicate that ripening in strawberry is associated with the expression of specific genes.     

An in vitro method for the conservation and storage of garlic (Allium sativum) germplasm

Shoot cultures of three garlic (Allium sativum) cultivars were kept in various temperatures and media in order to maintain their viability without subculture. A high level of viability was recorded after 16 months of culture at 4°C with 100 gl^-1 sucrose in B-5 medium.     

Introgression of wild species into the cultivated strawberry using synthetic octoploids

Synthetic octoploids reresent one method of integrating wild species germplasm into the cultivated octoploid strawberry. Several strawberry genotypes derived from Guelph synthetic octopoloids and 3–4 generations of outcrossing were evaluted for horticultural performance. Pollen stainability of the genotypes was improved by outcrossing and selection and was not considered a limiting factor to yield. Yield and berry weight of the genotypes improved to a level where several genotypes had yields as good as, or greater than, the mean of the check cultivars. There was no significant difference in the yield of genotypes that were either three or four outcrosses removed from the synthetic octoploids. Some genotypes displayed an everbearing habit accompanied by poor runnering characteristics which may have contributed to their reduced yield in the second season. Synthetic octoploids are composed of a diversity of germplasms distinct from the cultivated octoploid. However, by carefully selecting parents for the outcrossing program and rigorous selection for important horticultural traits, it was possible to restore performance close to the elite level in as few as three generations.     

In vitro storage of Eucalyptus grandis germplasm under minimal growth conditions

Slow growth-storage, for up to 10 months, has been achieved for Eucalyptus grandis shoot cultures by either the addition of 10 mg l⁻¹ abscisic acid to the growth medium or by the halving of nutrient supply (half MS) and removal of exogenous plant growth regulators. Reduction of light intensity or the addition of mannitol to the media were less effective in reducing growth rate. Isolated in vitro axillary buds encapsulated in calcium alginate and stored under low temperature and low light intensities survived for up to 3 months without loss in viability. Storage of such encapsulated fresh axillary buds at higher temperature resulted in a loss in viability. These methods have immediate applications to forestry breeding and clonal programs. This revised version was published online in June 2006 with corrections to the Cover Date.     

Characterization of LF9, an octoploid strawberry genotype selected for rapid regeneration and transformation

Cultivated strawberry (Fragaria ×ananassa) is a valuable crop, yet the absence of a rapid, high-throughput transgenic system has precluded meaningful application of biotechnology and translation of information from plant models to this crop. A new octoploid strawberry genetic line Laboratory Festival #9 has been identified, selected solely for its rapid regeneration and efficient transformation. Direct organogenesis has been achieved from all tissues tested, with rapidly-growing shoot initials visible in as few as 13 days. The conditions for optimal shoot regeneration, transformant selection, root generation, and plant acclimatization are presented. The progression from explant to plant in soil can be achieved in about 60 days. The development of transformation protocols in this rapid-cycling genotype allows high-throughput studies of gene function in the octoploid strawberry genetic background.     

Metabolic engineering in strawberry fruit uncovers a dormant biosynthetic pathway

Wild strawberry (Fragaria vesca) fruit contains several important phenylpropene aroma compounds such as eugenol, but cultivated varieties are mostly devoid of them. We have redirected the carbon flux in cultivated strawberry (Fragaria×ananassa) fruit from anthocyanin pigment biosynthesis to the production of acetates of hydroxycinnamyl alcohols, which serve as the precursors of the phenylpropenes, by downregulating the strawberry chalcone synthase (CHS) via RNAi-mediated gene silencing and, alternatively, by an antisense CHS construct. Simultaneous heterologous overexpression of a eugenol (EGS) and isoeugenol synthase (IGS) gene in the same cultivated strawberry fruits boosted the formation of eugenol, isoeugenol, and the related phenylpropenes chavicol and anol to concentrations orders of magnitude greater than their odor thresholds. The results show that Fragaria×ananassa still bears a phenylpropene biosynthetic pathway but the carbon flux is primarily directed to the formation of pigments. Thus, partial restoration of wild strawberry flavor in cultivated varieties is feasible by diverting the flavonoid pathway to phenylpropene synthesis through metabolic engineering.     

Conditions of transformation and regeneration of `Induka' and `Elista' strawberry plants

Efficiency of plants' transformation depends on many factors. The genotype, applied techniques and conditions of plant's modification and modified plant regeneration are the most important among them. In our studies regeneration and transformation conditions for two strawberry cultivars were determined and compared. Plants were transformed by Agrobacterium tumefaciens LBA₄₄₀₄ strain containing plasmid pBIN19 with nptII and gus-reporter genes. Experiment was carried out on more than 1300 leaf explants from each cultivar. Generally, `Induka' plants characterized with higher regeneration potential than `Elista'. The highest number of regenerated shoots was obtained on MS medium with 0.4 mg l ^–1 IBA and 1.8 mg l^–1 BA (3.5 and 1.8 shoots/explant for `Induka' and `Elista', respectively). After plant transformation number of regenerated, transgenic shoots was higher for `Elista' (on the average: 8.3 shoots/100 explants). The number of transgenic `Induka' shoots, obtained at the same conditions, was twice lower (4.2). Simultaneously `Induka' plants needed higher kanamycin concentration for transgenic explants selection than `Elista' (25 mg l^–1). Preliminary incubation of A. tumefaciens in LB or MS medium with acetosyringone and IAA resulted in increasing transgenic shoots number (per 100 explants: `Induka' 4.5, `Elista' 8.0–9.5 shoots). After using untreated bacteria for plants' transformation, number of transgenic plants varied (dependently on cultivar) from 3.8 to 7.0/100 explants. Applying LB or MS as basic medium as well as adding tobacco plant extract to these media did not significantly influence transformation efficiency.     

Molecular characterization of strawberry pathogen Gnomonia fragariae and its genetic relatedness to other Gnomonia species and members of Diaporthales

Gnomonia fragariae is a poorly studied ascomycete belonging to Diaporthales. Originally G. fragariae was considered a saprophyte occurring on dead tissues of strawberry plants. Recently this fungus was found in Latvia and Sweden, and it was proven to be the cause of severe root rot and petiole blight of strawberry. Thirteen isolates of this pathogen and several other Gnomonia species occurring on rosaceous hosts were characterized by molecular analysis using nucleotide sequences of partial LSU rRNA gene and the total ITS region. The homologous regions from relevant diaporthalean taxa available in the GenBank were also included and compared with the taxa sequenced in this study. Phylogenetic analyses revealed that G. fragariae, G. rubi, and Gnomonia sp. (CBS 850.79) were genetically different from G. gnomon, the type species of the genus, and other members of Gnomoniaceae. The analyses showed that G. fragariae and Hapalocystis were genetically very closely related, forming a phylogenetic clade, which is possibly presenting a new family in the Diaporthales. Morphological comparisons of the Gnomonia species on the basis of commonly used criteria for the taxonomy of Diaporthales, so far did not reveal any evident features for the polyphyletic status of Gnomonia.     

Protein synthesis during cold shock in barley tissues

Summary In barley (Hordeum vulgare L.) seedlings, a temperature step-down from 24 °C to 6°C (cold shock) determined a reduction in the incorporation of labeled aminoacids and modified the electrophoretic pattern of total proteins. At 6 °C some new proteins appeared and others were intensified (cold shock-induced proteins= CSPs); meantime, few proteins disappeared or were curtailed (cold-repressed proteins=CRPs). The majority of the proteins of the seedlings were labeled at about the same rate both at 6 °C and 24 °C, whereas at 0 °C only the cold shock proteins and a few others were detectable. The cold shock-induced variations of the protein profile differed in roots and in seed remnants which showed only some of the CSPs detected in roots. Total protein synthesis of barley genotypes Onice and Georgie, which have respectively a winter and spring growth habit, were similarly inhibited by a temperature drop. The two genotypes, however, showed some differences in the CSPs and CRPs pattern. Because Onice and Georgie have also a different thermotolerance, the hypothesis can be made that in barley specific CSPs are involved in conferring various degrees of cold resistance.     

Cryopreservation and long-term storage of pear germplasm

Summary Germplasm collections of vegetatively propagated crops are usually maintained as plants in fields or potted in greenhouses or screened enclosures. Safety duplication of these collections, as duplicate plants or separate collections, is costly and requires large amounts of space. Cryopreservation techniques which were recently developed for long-term storage of pear germalasm may offer an efficient alternative to conventional germplasm collection maintenance. Pear (Pyrus L.) germplasm may now be stored as seeds (species), dormant buds or pollen from field-grown trees, or shoot tips fromin vitro-grown plants (cultivars). Pear germplasm may now be cryopreserved and stored for long periods (> 100 yr) utilizing slow-freezing or vitrification ofin vitro-grown shoot-tips. Dormant bud freezing, pollen, and seed cryopreservation of other lines are being developed to complete the base collection forPyrus. This cryopreserved collection provides base (long-term) storage for the field-grown pear germplasm collection at the National Clonal Germplasm Repository, Corvallis, Oregon. Based on a presentation at the 1997 Congress on In Vitro Biology held in Washington, D.C., June 14–18, 1997.     

Tracking the evolutionary history of polyploidy in Fragaria L. (strawberry): New insights from phylogenetic analyses of low-copy nuclear genes

Phylogenetic utility of two nuclear genes (GBSSI-2 and DHAR) was explored in genus Fragaria in order to clarify phylogenetic relationships among taxa and to elucidate the origin of the polyploid species. Orthology of the amplified products was assessed by several methods. Our results strongly suggest the loss of one GBSSI duplicated copy (GBSSI-1) in the Fragariinae subtribe. Phylogenetic analyses provided new insights into the evolutionary history of Fragaria, such as evidence supporting the presence of three main diploid genomic pools in the genus and demonstrating the occurrence of independent events of polyploidisation. In addition, the data provide evidence supporting an allopolyploid origin of the hexaploid F. moschata, and the octoploids F. chiloensis, F. iturupensis and F. virginiana. Accordingly, a new pattern summarizing our present knowledge on the Fragaria evolutionary history is proposed. Additionally, sequence analyses also revealed relaxed constraints on homoeologous copies at high ploidy level, as demonstrated by deletion events within DHAR coding sequences of some allo-octoploid haplotypes.     

Gene action for cold tolerance in chickpea

Summary Six crosses were investigated using combining ability and generation mean analyses for reaction to cold tolerance in chickpea (Cicer arietinum L.). The combining ability variances revealed the significance of both additive and nonadditive gene effects, with preponderance of additive gene effects. The generation mean analysis revealed the presence of genie interactions in addition to additive and dominance gene effects. Among the interactions, additive×additive and dominance×dominance with duplicate epistasis were present. Cold tolerance was dominant over susceptibility to cold. Selection for cold tolerance would be more effective if dominance and epistatic effects were reduced after a few generations of selfing.Joint contribution from ICARDA and ICRISAT (International Crops Research Institute for the Semi-Arid Tropics), Patancheru P.O., A.P. 502 324, India. ICRISAT JA No. 1239.