Malcolm C. Elliott

Senescence-induced ectopic expression of the A. tumefaciens ipt gene in wheat delays leaf senescence, increases cytokinin content, nitrate influx, and nitrate reductase activity, but does not affect grain yield

The manipulation of cytokinin levels by senescence-regulated expression of the Agrobacterium tumefaciens ipt gene through its control by the Arabidopsis SAG12 (senescence-associated gene 12) promoter is an efficient tool for the prolongation of leaf photosynthetic activity which potentially can affect plant productivity. In the present study, the efficiency of this approach was tested on wheat (Triticum aestivum L.)-a monocarpic plant characterized by a fast switch from vegetative to reproductive growth, and rapid translocation of metabolites from leaves to developing grains after anthesis. When compared with the wild-type (WT) control plants, the SAG12::ipt wheat plants exhibited delayed chlorophyll degradation only when grown under limited nitrogen (N) supply. Ten days after anthesis the content of chlorophyll and bioactive cytokinins of the first (flag) leaf of the transgenic plants was 32% and 65% higher, respectively, than that of the control. There was a progressive increase in nitrate influx and nitrate reductase activity. However, the SAG12::ipt and the WT plants did not show differences in yield-related parameters including number of grains and grain weight. These results suggest that the delay of leaf senescence in wheat also delays the translocation of metabolites from leaves to developing grains, as indicated by higher accumulation of ((15)N-labelled) N in spikes of control compared with transgenic plants prior to anthesis. This delay interferes with the wheat reproductive strategy that is based on a fast programmed translocation of metabolites from the senescing leaves to the reproductive sinks shortly after anthesis.

Efficient co-transformation of Nicotiana tabacum by two independent T-DNAs, the effect of T-DNA size and implications for genetic separation

The co-transformation of a single plant genome with two independent T-DNA regions provides opportunities for genetic separation in subsequent generations. In an effective strategy, co-delivery events must form a high proportion of the total transformed population. In this study, using the model plant species tobacco (Nicotiana tabacum), it was shown that the frequency of co-transformation within a given T0 population could be as high as 100% and this was found to be dependent, at least in part, on designing the plasmid vectors so that the kbp size of the first selected T-DNA region was >2-fold that of the designated T-DNA region for co-transfer. Overall, 40–50% of T0 lines demonstrated the capacity for segregational separation of co-transformed T-DNA regions. Hence, the estimate of the required number of total transformants for such an independent strategy may seem to be as little as 2-fold that for a conventional, single T-DNA strategy, but we strongly temper such estimates with indications that high co-transformation frequencies may be associated with a higher incidence of linkage. In this co-transformation study we used a single (Agrobacterium) strain system in which a single binary plasmid contained either two or three T-DNA regions, each with a selectable marker. This arrangement could reveal that ‘read-through’ events within the Agrobacterium cells, resulting in the co-transfer of adjacent T-DNA regions as a single linked unit, accounted for up to 20% of co-transformed plant lines. Such read-through co-delivery appeared to be more frequent from the ‘supervirulent’ EHA101 A. tumefaciens strain, compared to the ‘ordinary’ LBA4404 strain. By using the binary plasmid with three selectable T-DNA regions, we have been able to consider the frequency of co-integration of a third independent T-DNA within a T0 subpopulation of co-transformants. This was found to be higher than expected. These observations were applied to the co-transfer of (unwanted) plasmid backbone sequences and showed that screening against such sequences may add a significant factor in achieving the desired, final genotype.

The use of visual marker genes as cell-specific reporters of Agrobacterium-mediated T-DNA delivery to wheat (Triticum aestivum L.) and barley (Hordeum vulgare L.).

Transfer of T-DNA from Agrobacterium tumefaciens and A. rhizogenes to cells of wheat (Triticum aestivum L.) and barley (Hordeum vulgare L.) is demonstrated following the inoculation of immature embryos and immature embryo-derived callus. Agrobacterium T-DNA vectors containing the C1/Lc anthocyanin-biosynthesis regulatory genes, the gusA gene or a synthetic green fluorescent protein gene (sgfp-S65T) were constructed from original binary vectors. The visual T-DNA markers were used as cell-autonomous reporters of early Agrobacterium-mediated transformation events in the wheat and barley cells. This localization of the transformed cells revealed a non-random distribution throughout each embryo and callus piece.

Agrobacterium-mediated transformation of élite indica and japonica rice cultivars

A rapid, efficient, routine system has been established forAgrobacterium tumefaciens-mediated production of hundreds of fertile transgenic plants from commercially important rice cultivars, including an indica cultivar, Pusa Basmati 1. Calli induced from embryos of mature rice seeds were cocultivated withA. tumefaciens strain LBA4404 carrying the plasmid pTOK233, then exposed to hygromycin selection followed by an efficient regeneration system. Based on the total number of calli co-cultivated, the transformation frequencies of independent transgenic rice plants including cultivars Pusa Basmati 1, E-yi 105, E-wan 5 and Zhong-shu-wan-geng, were 13.5, 13.0, 9.1, and 9.3%, respectively. T1 seeds were harvested within 7–8 mo of initiation of mature embryo cultures. Data from Southern hybridization analysis proved that foreign genes on T-DNA were stably integrated into the rice genome at low copy/site numbers. Mendelian inheritance of the transgenes was confirmed in T1 progeny.

Regeneration of diploid annual medics via direct somatic embryogenesis promoted by thidiazuron and benzylaminopurine

Abstract The development of a simple and rapid procedure for direct somatic embryogenesis from wild Medicago spp. (M. truncatula, M. littoralis, M. murex, M. polymorpha) has exploited various explants including meristematic zones. Phytogel-solidified medium supplemented with thidiazuron or 6-benzylaminopurine at different concentrations effectively promoted this process. The first somatic structures emerged within 20 days of culture initiation. Histological analyses confirmed the nature of the directly formed embryos. Secondary embryogenesis was also observed. Cuttings of clusters of primary and secondary embryos were used for cyclic production of new embryo generations. Regenerated plants with well-developed root systems on medium with reduced levels of macroelements and sucrose were easily adapted to a greenhouse.

A simple method for the production of highly competent cells of Agrobacterium for transformation via electroporation.

The introduction of binary plasmids intoAgrobacterium hosts forAgrobacterium-mediated transformation of plants is most readily achieved by electroporation. However, occasionally, no transformed colonies are recovered and the transformation program is delayed. Poor transformation rates are commonly associated with particular combinations ofAgrobacterium strains and plasmid-selection markers. In order to avoid this problem, it is important for the bacteria to have a highly competent status for reception of plasmid DNA. It is also important to optimize the level of antibiotic for the selection of transformed colonies. In this article, we demonstrate that transformation competence is strongly related to the phase of growth at which a bacterial culture is prepared for electroporation, and we describe a simple procedure that allows the level of transformation-competent cells to be maximized. We have observed that there is significant variation between transformedAgrobacterium strains in the levels of antibiotic tolerance; we define the antibiotic levels that are appropriate for selection of threeArgobacterium tumefaciens (EHA101, LBA4404, C58) and twoArgobacterium rhizogenes (LBA9402, Ar2626) strains, transformed with three alternative resistance markers (spectinomycinres, kanamycinres, and gentamycinres).

THIDIAZURON-INDUCED ORGANOGENESIS AND SOMATIC EMBRYOGENESIS IN SUGAR BEET (BETA VULGARIS L.)

SummaryImproved in vitro tissue culture systems are needed to facilitate the application of recombinant DNA technology to the improvement of sugar beet germplasm. The effects of N6-benzyladenine (BA) and thidiazuron (TDZ) pretreatment on adventitious shoot and somatic embryogenesis regeneration were evaluated in a range of sugar beet breeding lines and commercial varieties. Petiole explants showed higher frequencies of direct adventitious shoot formation and produced more shoots per explant than leaf lamina explants. TDZ was more effective than BA for the promotion of shoot formation. The optimal TDZ concentrations were 2.3–4.6 μM for the induction of adventitious shoot regeneration. Direct somatic embryogenesis from intact seedlings could be induced by either BA or TDZ. TDZ-induced somatic embryogenesis occurred on the lower surface of cotyledons at concentrations of 0.5–2μM and was less genotype-dependent than with Ba. A high frequency of callus induction could be obtained from seedlings and leaf explants, but only a few of the calluses derived from leaf explants could regenerate to plants via indirect somatic embryogenesis. These results demonstrated that TDZ could prove to be a more effective cytokinin for in vitro culture of sugar beet than BA. Rapid and efficient regeneration of plants using TDZ may provide a route for the production of transgenic sugar beet following Agrobacterium-mediated transformation.

Use of the GFP reporter as a vital marker for Agrobacterium-mediated transformation of sugar beet (Beta vulgaris L.)

Molecular approaches to sugar beet improvement will benefit from an efficient transformation procedure that does not rely upon exploitation of selectable marker genes such as those which confer antibiotic or herbicide resistance upon the transgenic plants. The expression of the green fluorescent protein (GFP) signal has been investigated during a program of research that was designed to address the need to increase the speed and efficiency of selection of sugar beet transformants. It was envisaged that the GFP reporter could be used initially as a supplement to current selection regimes in order to help eliminate “escapes” and perhaps eventually as a replacement marker in order to avoid the public disquiet associated with antibiotic/herbicide-resistance genes in field-released crops. The sgfp-S65T gene has been modified to have a plant-compatible codon usage, and a serine to threonine mutation at position 65 for enhanced fluorescence under blue light. This gene, under the control of the CaMV 35S promoter, was introduced into sugar beet via Agrobacterium-mediated transformation. Early gene expression in cocultivated sugar beet cultures was signified by green fluorescence several days after cocultivation. Stably transformed calli, which showed green fluorescence at a range of densities, were obtained at frequencies of 3–11% after transferring the inoculated cultures to selection media. Cocultivated shoot explants or embryogenic calli were regularly monitored under the microscope with blue light when they were transferred to media without selective agents. Green fluorescent shoots were obtained at frequencies of 2–5%. It was concluded that the sgfp-S65T gene can be used as a vital marker for noninvasive screening of cells and shoots for transformation, and that it has potential for the development of selectable marker-free transgenic sugar beet.

Agrobacterium-mediated stable transformation of cell suspension cultures of barley (Hordeum vulgare)

Barley (Hordeum vulgare L. cvs. Igri and Dissa) cell suspension cultures, which had been initiated from immature embryo-derived (IED) and microspore-derived (MSD) callus, were co-cultivated with various Agrobacterium tumefaciens strains. The T-DNA vectors contained visually-detectable marker genes (C1/Lc orgusA-intron), as reporters of transient T-DNA transfer, and also drug resistance genes (hph or bar) to facilitate selection of stably transformed cell lines. A set of normal binary vectors in a super-virulent Agrobacterium strain [EHA101(pBECKS)] and also a super-binary vector [LBA4404(pTOK233)] were used in this study. Cells of the suspension cultures which received T-DNA were able to proliferate under selection regimes and a number of hygromycin- or phosphinothricin-resistant barley callus lines were isolated which expressed a co-transferred gusA gene. To ensure homogeneity of the cell lines, prolonged tissue culture regimes were used but these resulted in a loss of the capacity to regenerate plants from the transgenic callus lines. The frequency of recovery of transformed callus lines ranged from 0.3% to 2.9%. Southern blot analyses of the transformed callus lines confirmed the presence of the marker genes and demonstrated them to be associated with DNA which was distinct from that of the original Agrobacterium plasmid. Furthermore, independent transgenic lines showed diverse patterns of hybridising bands. These data suggest that the T-DNA fragment was stably maintained through integration into the genomes of the barley cell lines.

Production of fertile transgenic wheat plants via tissue electroporation.

Electroporation has been used effectively to deliver DNA into the tissue of intact wheat immature embryos. Transformed plantlets have been recovered after electroporation using field strengths of 275 and 750 V/cm, 960-µF capacitor and 50 µg/ml of linear plasmid DNA, containing bar and uidA genes. The field strength of 750 V/cm proved to be more effective for DNA delivery (estimated by transient GUS expression) and for recovery of transformed plants (two transgenic plants were recovered with an efficiency of 0.4%). After application of a field strength of 275 V/cm there was no visual evidence of transient GUS expression, but one transgenic plant was recovered with an efficiency of 0.2%, based on the number of electroporated embryos. This indicates that the amount of DNA delivered into the cells was too low for visual identification of transient GUS expression and that GUS expression may not provide an appropriate assessment of the efficiency of DNA delivery. Southern blot hybridisation has revealed a low copy number of transgene integration with some rearrangements in integrated loci. None of the transgenic plants has shown any visual GUS expression, although we could amplify the transcript of the uidA gene in T(0) progeny using RT-PCR. This may indicate that suppression of uidA expression occurred at the post-transcriptional level. The efficiency of tissue electroporation is still dependent on the quality of the plant material which is used but the transformation events were reproducible from one group of experiments to another. At present, this technique is dependent on a combination of factors including pretreatments of the recipient tissue, quality of tissue culture and optimisation of electroporation conditions.