An efficient method for in vitro regeneration from immature inflorescence explants of Canadian wheat cultivars

Fertile, green plants were regenerated from immature inflorescence explants from each of four Canadian wheat cultivars. The cultivars were representative of four classes of Canadian wheat. Explants from immature inflorescences of three size ranges were cultured on two types of media: MSI/MSR, which contains 1650 mg l^-1 NH₄NO₃and sucrose as a carbon source, and BII/BIR, which contains 250 mg l^-1 NH₄NO₃and maltose as a carbon source. Regeneration from all cultivars was significantly better on BII/BIR media than on MSI/MSR media. On BII/BIR media, `AC Karma', `Plenty', and `Fielder' gave the highest number of shoots per 10 explants, where the explants were derived from immature inflorescences 5.1 to 10.0 mm in length. 'Columbus' did not regenerate on MSI/MSR medium, and regenerated poorly on BII/BIR medium. Differences were found between cultivars with regard to the number of regenerant plants produced with the best treatments: `Plenty' produced 16.1 shoots per 10 explants, `AC Karma' 12.4, `Fielder' 6.4, and `Columbus' 2.2.     

In vitro normal and variant development of t'ef (Eragrostis tef) spikelets

Spikelets of t'ef, Eragrostis tef were cultured from the pre-anthesis stage to seed maturation, although only a small proportion of these seeds germinated to produce adult plants. A liquid culture medium originally formulated for wheat spikelets was used and it is of interest that grass stigmas normally classified as dry function under these conditions. Varietal differences of response were observed and examples were found where although seed setting within the spikelet was less than under in vivo situation. The implications are considered for spikelet culture in an old genus such as Eragrostis where one species, E. tef, is recognised as conspicuously variable.     

In vitro pollen maturation and successful seed production in detached spikelet cultures in wheat (Triticum aestivum L.)

Summary Two spring wheat genotypes (cv Orofen and Chinese Spring) were compared for their in vitro pollen maturation capacity in detached spikelet cultures in a defined solid medium. Under these in vitro conditions Chinese Spring produced normal trinucleate pollen in 66.8% and Orofen in only 37.5%. In both cultivars the pollen maturation process from the middle uninucleate stage took approximately 3 days longer in vitro than in vivo. The pollen maturation time depended on the microspore developmental stage at the time that the culturing started. The viability, germination capacity, and fertilizing ability of the in vitro matured pollen also differed between the two genotypes. The seed set achieved in vitro (averagely 12.8%) offers promise for the practical application of this method for producing controlled or selected offspring.     

Inheritance of grain proteins in wheat

Summary Diallel crosses between five divergent vulgare wheat cultivars were made in order to evaluate the mode of inheritance and combining ability of grain proteins. Significant differences in grain protein content were found between cultivars and their hybrids. It was established that the inheritance of seed protein in the F₁ generation included both additive and non-additive gene action.     

In vitro microspore reaction of different German wheat cultivars

Summary The in vitro microspore androgenesis reaction of 25 commercial German spring (including 4 Triticum durum) and 50 winter wheat cultivars was investigated. Tremendous genotypical differences were found in microspore response. The best-responding winter wheat cultivai, Florida, is characterized by the presence of a 1B/1R wheat-rye translocation chromosome. The significance of this finding and other genetic systems for future use of haploids in plant breeding is discussed.     

Isolated wheat microspore culture

The use of doubled haploid plants in a wheat breeding program requires an efficient haploid production system. While the techniques for producing doubled haploids from anther culture are well established, those for isolated microspores are complicated and inefficient. Four methods of isolating microspores from anthers (blending, stirring, macerating, and floating) were compared. Isolated microspores were washed and cultured in liquid medium. The effects of pre-isolation mannitol conditioning, cell density, culture dilution, and sucrose centrifugation on microspore viability were evaluated. Isolation by blending gave the highest initial microspore viability (75%). Mannitol conditioning and purification by sucrose centrifugation had a detrimental effect on initial viability. An initial microspore density of 2 × 10⁵ microspores per ml was necessary for continued microspore viability. One hundred and nine haploid or spontancously doubled haploid plants were regenerated from microspores isolated without mannitol conditioning using the blending method. Based on this research, blender isolation with an initial density of 2 × 10⁵ microspores per ml is recommended for isolated microspore culture.Abbreviations LSmean least square mean - MES 2-N-morpholinoethane sulfonic acid - 2,4-d 2,4-dichlorophenoxyacetic acid - NAA -naphtaleneacetic acid     

The effects of KNO3 concentration in callus induction medium for wheat anther culture

KNO₃ concentration was found to significantly affect the anther culture of wheat (Triticum aestivum L.). When KNO₃ was increased from 0 to 15 mM (in cultivar Jinghua 1) or from 10 to 15 mM (in cultivars 2531-10, Xiaoyan 759 and Norin 10), the callus induction frequency increased significantly. When KNO₃ was increased further above 20 mM, the callus induction frequency decreased significantly in all the tested cultivars. The subsequent frequency of green plantlet regeneration increased significantly, and the ratio of green to albino regenerants increased sharply when KNO₃ concentration increased. Further experiments found that the decrease of callus induction frequency in the medium with too much KNO₃ might be caused by NO₃ ^- ion alone, while the effect of KNO₃ on green plantlet regeneration might be caused by both K⁺ and NO₃ ^- ions, and that the effects of NO₃ ^- concentration were independent of NH₄ ⁺ concentration in the medium.     

Endogenous hormone concentrations and embryogenic callus development in wheat

Immature zygotic embryos of two wheat (Triticum aestivum L.) genotypes, known for their different ability to generate embryogenic callus, were used as initial explants to establish callus cultures. Embryogenic and non-embryogenic calluses were obtained from the competent genotype (`Combi'), while only non-embryogenic callus was produced by the incompetent one (`Devon'). The morphogenetic competence of each callus type was evaluated by transferring some segments to regeneration conditions. The endogenous hormone concentrations (free indole-3-acetic acid [IAA], abscisic acid [ABA], gibberellins ₁, ₃ and ₂₀ [GAs], zeatin/zeatin riboside [Z/ZR] and N ⁶[²-isopentenyl] adenine/ N ⁶[²-isopentenyl] adenosine; [iP/iPA]) of the initial explants were determined by means of radio-immunoassay and showed that the only difference was the higher concentration of ABA found in the embryos of the most competent genotype; whose embryos showed a reduced rate of precocious germination. When analysing the endogenous hormone concentrations in the various callus types generated in each genotype, it was found that only differences in the free IAA concentrations were associated with variations in the morphogenic properties of the calluses. Higher concentrations of endogenous free IAA were typical of embryogenic callus cultures. It was also observed that a loss in the embryogenic competence of the calluses, due to a prolonged time of culture, occurred concomitantly with a reduction in free IAA concentrations, practically to the concentrations found in the non-embryogenic calluses.     

Recent advances in wheat transformation

Summary Since the first report of wheat transformation in the early 1990s, genetic engineering of wheat has evolved rapidly. Several laboratories worldwide have reported the production of fertile transgenic wheat plants using a variety of methods. While there are several innovative and promising approaches for wheat transformation using different explants as targets for transformation, different methods of transformation, and different selection schemes, the most common approach to wheat transformation is the bombardment of tissue derived from immature embryos followed by selection based on resistance to the bar gene. Even with all these successful reports, hurdles still exist for this recalcitrant crop. Of these hurdles, low transformation rates, tools for transgene expression, and transgene silencing in subsequent generations are probably the most critical. This review will provide an overview of wheat transformation in the past decade, addressing both positive and negative factors that effect transformation while highlighting the successes of the past and prospects for the future.     

Molecular analysis of plants regenerated from embryogenic cultures of wheat (Triticum aestivum L.)

Total DNAs of plants regenerated from immature embryo-derived 2-month-old embryogenic calli of wheat (cultivars Florida 302, Chris, Pavon, RH770019) were probed with six maize mitochondrial genes (atpA, atp6, apt9, coxI, coxII, rrn18-rrn5), three hypervariable wheat mitochondrial clones (K, K3, X2), five random pearl millet mitochondrial clones (4A9, 4D1, 4D12, 4E1, 4E11) and the often-used wheat Nor locus probe (pTA71), in order to assess the molecular changes induced in vitro. In addition, protoplast-derived plants, and 24-month-old embryogenic and non-embryogenic calli and cell suspension cultures of Florida 302 were also analyzed. No variation was revealed by the wheat or millet mitochondrial clones. Qualitative variation was detected in the nonembryogenic suspension culture by three maize mitochondrial genes (coxI, rrn18-rrn5, atp6). A callus-specific 3.8-kb Hind III fragment was detected in all four cultivars after hybridization with the coxI gene. The organization of the Nor locus of the plants regenerated from Florida 302 and Chris was stable when compared to their respective control plants and calli. The Nor locus in regenerants of Pavon and RH, on the other hand, was found to be variable. However, Nor locus variability was not observed in 14 individual seed-derived control plants from either Pavon or RH sources. In Pavon, a 3.6-kb Taq I or a 5.6-kb Bam HI+ Eco RI fragment was lost after regeneration. In one of the RH regenerants, which lost a fragment, an additional fragment was observed.     

Three sucrose transporter genes are expressed in the developing grain of hexaploid wheat

A family of three cDNAs, designated TaSUT1A, 1B and 1D, encoding sucrose transporter (SUT) proteins was isolated from a hexaploid wheat (Triticum aestivum) endosperm library. The cDNA sequences are 96% identical but are distinguishable from one another by virtue of a size polymorphism in the 3-untranslated region (UTR). The predicted amino acid sequences are 98% identical and are highly similar to the sucrose transporters from rice, maize and barley. A gene for TaSUT1 was isolated from genomic libraries of Aegilops tauschii (the donor of the D genome of wheat) and the coding sequence found to be identical to that of TaSUT1D cDNA. There is only one copy of each TaSUT1 gene in hexaploid wheat and it is located on chromosome 4. Genomic Southern analysis and PCR analysis across the 3 polymorphic region of hexaploid, tetraploid and progenitor diploid wheat DNAs established that the TaSUT1A gene was present in the putative A-genome progenitor, T. monococcum, and that the TaSUT1B gene was present in the putative B-genome progenitor, T. searsii. All three TaSUT1 genes are expressed at high levels in filling grain, showing a good correlation with the developmental time course of growth. This reinforces the view that in cereals a major role of SUT1 is in the post-phloem sugar transport pathway associated with seed filling.     

An evaluation of mitochondrial heterosis and in vitro mitochondrial complementation in wheat,barley and maize

Summary Two families each of wheat (Triticum aestivum L.), barley (Hordeum vulgare L.) and maize (Zea mays L.) were studied for mitochondrial heterosis and in vitro mitochondrial complementation. Inbred parents and their hybrids were compared for seedling heights and rate of oxygen uptake by the whole tissue to find out if the hybrids showed greater growth and respiratory activity at the seedling stage. Further comparisons were made by isolating mitochondria from the seedling tissues and measuring their ADP0 ratio, respiratory control ratio and cytochrome c oxidase activity for mitochondrial heterosis. Mixtures of parental mitochondria were similarly compared with parental and hybrid mitochondria for in vitro mitochondrial complementation. No evidence for mitochondrial heterosis or in vitro mitochondrial complementation was found, nor any correlation between the different mitochondrial parameters, seedling heights or rates of oxygen uptake by seedling tissue. The suggested use of mitochondrial heterosis and in vitro mitochondrial complementation for plant breeding is discussed.Data for this paper is taken from the author's dissertation written as a part of Ph.D. degree requirements at the Biology Department, Texas A & M University, College Station, Texas     

Effects of free and chelated iron on in vitro androgenesis in barley and wheat

A suitable form of iron supplement in the induction medium was found to be important for further development of induced pollen embryos in barley and wheat cultivars (genotypes), especially those providing few green plants viain vitro androgenesis. Genotypes able to regenerate many green plants were less susceptible to the lack of iron in induction medium. Although Fe-EDTA was found to be a suitable form of iron in the induction medium, androgenesis was also induced on media containing non-chelated iron (Fe²⁺ and Fe³⁺ ions). EDTA alone without iron inhibited the androgenic response even in the wheat cv. Florida, a model cultivar for androgenesis in wheat. In all barley cultivars under study including cv. Igri, a model cultivar for androgenesis in barley, EDTA alone caused an almost total suppression of androgenesis. This revised version was published online in June 2006 with corrections to the Cover Date.     

Enzyme activities associated with developing wheat(Triticum aestivum L.) grain amyloplasts

Intact amyloplasts from endosperm of developing wheat grains have been isolated by first preparing the protoplasts and then fractionating the lysate of the protoplasts on percoll and ficoll gradients, respectively. Amyloplasts isolated as above were functional and not contaminated by cytosol or by organelles likely to be involved in carbohydrate metabolism. The enzyme distribution studies indicated that ADP-glucose pyrophosphorylase and starch synthase were confined to amyloplasts, whereas invertase, sucrose synthase, UDP-glucose pyrophosphorylase, hexokinase, phosphofructokinase-2 and fructose-2,6-P₂ase were absent fro the amyloplast and mainly confined to the cytosol. Triose-P isomerase, glyceraldehyde-3-P dehydrogenase, phosphohexose isomerase, phosphoglucomutase, phosphofructokinase, aldolase, PPi-fructose-6-P-1 phosphotransferase, and fructose-l,6-P₂ase, though predominantly cytosolic, were also present in the amyloplast. Based on distribution of enzymes, a probable pathway for starch biosynthesis in amyloplasts of developing wheat grains has been proposed.     

Effect of genotype and medium on wheat (Triticum aestivum L.) anther culture

Four winter wheat (Triticum aestivum L.) and two spring wheat cultivars were evaluated in anther culture on three to four different media for their ability to initiate callus and green plants. Five media were used in the experiment: stored-potato medium with Ficoll 400, fresh-potato medium with Ficoll 400, fresh-potato medium with agar, fresh-potato liquid medium without agar or Ficoll 400, and a one tep 85D12-3 medium. Greatly different frequencies of calli and/or green plants were obtained from different cultivars and media. The callus initiation frequency varied from 2.7% for Arapahoe to 52% for Pavon, both on the stored potato medium with Ficoll 400. The frequency of green plant regeneration ranged from 0% for Arapahoe and Siouxland on the stored-potato medium with Ficoll 400 and 0% for Redland and Arapahoe in the fresh-potato medium with Ficoll 400 to 12% for Chris in the 85D12-3 medium (one-step procedure). Chris and Centurk 78, previously reported as having high levels of response, had significantly higher (P < 0.05) frequencies of green plant regeneration on the 851312-3 medium than the other cultivars. An unexpected observation is that wet MSC^– medium enhanced callus regeneration more than a drier MSC^– medium.     

Nitrate reductase activity (in vivo and in vitro) of ditelosomic stocks of wheat (Triticum aestivum L.)

The nitrate reductase activities (NRA) of 31 ditelosomic stocks were compared with that of the control plant [Chinese Spring (CS) euploid], using in vivo and in vitro assay procedures that had been optimized with respect to the euploid. Fourteen stocks exhibited significant differences in in vivo NRA from that of the euploid; the effect of removal of a chromosome arm was always to increase NRA. Eight of these stocks showed similar effects in vitro, although in three, a casein-sensitive factor had to be eliminated before the difference was expressed. Homoeologous group effects were evident among ditelosomics of groups 2, 4, and 7, while for three chromosomes (2D, 7A, and 7B), removal of either arm resulted in a similar increase in NRA in vivo and probably in vitro.P. W. Jones was supported by a Science Research Council C.A.S.E. award with the Plant Breeding Institute, Cambridge, U.K.     

Evidence for microspore embryogenesis in wheat anther culture

Summary In wheat, plants may be regenerated from microspores via direct embryogenesis or organogenesis or embryogenesis from callus. Light and scanning electron microscopy were used to carefully study morphogenesis of microspore-derived plants from anther culture on modified 85D12 starch medium and to determine whether the plants were formed via organogenesis or embryogenesis. Our results indicate that plants are formed via embryogenesis from microspores. Evidence for embryogenesis included the formation of the epidermis and a suspensorlike structure (21 days after culture), followed by initiation of an apical meristem, differentiation of the scutellum, and embryo elongation. At 28 days in culture, the embryo possessed a well-developed scutellum and axis with suspensor. Embryogenesis was further confirmed by coleoptile and radicle elongation during germination when the embryos were cultured on medium supplemented with kinetin with or without coconut water. In this system, an average 67 microspores per responsive anther began cell division but only 3.69 embryos were formed per responsive anther after 6 wk. Adventitious embryos could be induced if the embryos, once formed, remained on initiation medium for 10 wk instead of being transferred to regeneration medium. Developmental stages which may be amenable to changes that could enhance plant production were identified. The potential to use this information to enhance plant production is discussed.     

Cultivar and cultivar x environment effects on the development of callus and polyhaploid plants from anther cultures of wheat

Summary Plants of three common wheat (Triticum aestivum L. em. Thell) cultivars and one randomly selected doubled-haploid line derived by anther culture from each of the three cultivars were each grown in three environments, a field environment, a greenhouse environment, and a growth chamber environment. Anthers containing largely miduninucleate to late uninucleate microspores were cultured and calli were induced to regenerate plants in order to assess the effects of cultivar, cultivar family (cultivar and corresponding doubled-haploid derivative), anther-donor plant environment, and cultivar X environment interaction on androgenic responses. Large differences in response were observed among cultivars as well as between cultivars and doubled-haploids. Differences between cultivar and doubled-haploid within cultivar family usually resulted from higher frequency of response in the cultivar, contrary to the hypothesis that anther culture per se constitutes a general selective device for superior androgenic responses. Also, in a second experiment, anther callusing frequency was greater in the cultivar Kitt than in any of five unique doubled-haploid lines derived from Kitt. Significant effects were also observed in the first experiment for the interactions of cultivar family X environment as well as doubled-haploid vs. cultivar X environment, although the effect of environment itself was less significant than these interactions.Contribution from the USDA, SEA, AR, Beltsville, Md, and the Department of Agronomy, University of Maryland, College Park, Md, as scientific article No. A-3413, contribution No. 6486     

Comparison of media for their aptitude in wheat anther culture

Different media were evaluated with anthers of five spring wheat (Triticum aestivum L.) genotypes for their ability to produce embryos and green plants in anther culture. Our first experiment showed that the addition of a combination of 19 amino acids significantly increased the number of embryos and green plants obtained. The mean number of green plants per 100 anthers for the two genotypes in this experiment, HY320 and B723, went from 28.2 without amino acids in the medium, to 46.7 with addition of amino acids. Our second experiment with the genotypes HY320, Wim and Laval-19 showed that liquid medium with Ficoll is more efficient for anther culture (9.9 green plants/100 anthers) than solid (0 green plants), gelationous media (2.5 green plants/100 anthers) or liquid medium with Membrane Rafts (0 green plants; Hoechst Celanese Corp.). Our third experiment revealed that the effect of replacement of sucrose by maltose varied with the genotype of the donor plant. Maltose partially inhibited the androgenesis of three responsive genotypes, HY320, Wim and Reliance (40.3 green plants/100 anthers instead of 43.9 with sucrose), while maltose significantly increased the androgenesis of the recalcitrant genotype Laval-19 (10.8 green plants/100 anthers instead of 5.4 with sucrose). An amino acid x maltose interaction was also observed. Amino acids without maltose increased androgenesis, but the addition of maltose to the amino acid-enriched medium eliminated this positive effect of the amino acids.     

Improvement of green plant regeneration by manipulation of anther culture induction medium of hexaploid wheat

Anthers of three hexaploid wheat (Triticum aestivum L.) genotypes with high frequencies of albino regenerants in anther culture were compared to DH after inoculation on medium supplemented with ficoll, colchicine or maltose separately, pair-wise or combined, in an attempt to increase green plant regeneration. Maltose treatment produced more green regenerated plants than sucrose for all of the genotypes. The three chemicals combined in anther medium either reduced green plant regeneration or did not yield significantly different numbers of green regenerated plants compared to the maltose treatment. With DH fewer embryo-like structures (ELS) were obtained per 100 cultured anthers on all medium containing colchicine but greater frequencies of green plants per 100 ELS were obtained. It appeared that the increase in green regenerated plants per 100 ELS was due to a better quality of embryos that were capable of regenerating into green rather than albino plantlets. Smaller increases in green plants per 100 ELS were observed in ICR 4 and V-15 on colchicine containing medium compared to DH. Genotypic differences in anther culture response were observed for ELS per 100 cultured anthers (increased for V-37, decreased for DH and approx. the same for ICR 4 and V-15 in medium with all three chemicals compared to the sucrose control).