Transformation of white poplar (Populus alba L.) with a novel Arabidopsis thaliana cysteine proteinase inhibitor and analysis of insect pest resistance

Transgenic white poplar (Populus alba L.) plants expressing a novel Arabidopsis thaliana cysteine proteinase inhibitor (Atcys) gene have been produced using Agrobacterium tumefaciens-mediated gene transfer. Internodal stem segments of cv. Villafranca were co-cultivated with the EHA105 pBI-Atcys A. tumefaciens strain. Sixteen putative transgenic plant lines were regenerated from different calli with a transformation efficiency of 11%. The integration and expression of the cysteine proteinase inhibitor (Atcys) gene into the plant genome was confirmed by Southern and northern blot analyses. Papain inhibitory activity was detected in poplar transgenic tissues by means of a specific in vitro assay. Such activity was sufficient to inhibit most of the digestive proteinase activity of chrysomelid beetle (Chrysomela populi L.) and confer resistance to C. populi larvae on selected transgenic plants. A close correspondence between the inhibition of papain and resistance to poplar leaf beetle was observed in all tested transgenic lines. Our results indicate that Atcys could be succesfully employed in breeding programmes aimed at the selection of new poplar genotypes resistant to major insect pests.     

Expression of the PsMT A1 gene in white poplar engineered with the MAT system is associated with heavy metal tolerance and protection against 8-hydroxy-2′-deoxyguanosine mediated-DNA damage

Marker-free transgenic white poplar (Populus alba L., cv ‘Villafranca’) plants, expressing the PsMT _A1 gene from Pisum sativum for a metallothionein-like protein, were produced by Agrobacterium tumefaciens-mediated transformation. The 35SCaMV-PsMT _A1 -NosT cassette was inserted into the ipt-type vector pMAT22. The occurrence of the abnormal ipt-shooty phenotype allowed the visual selection of transformants, while the yeast site-specific recombination R/RS system was responsible for the excision of the undesired vector sequences with the consequent recovery of normal marker-free transgenic plants. Molecular analyses confirmed the presence of the 35SCaMV-PsMT _A1 -NosT cassette and transgene expression. Five selected lines were further characterized, revealing the ability to withstand heavy metal toxicity. They survived 0.1 mM CuCl₂, a concentration which strongly affected the nontransgenic plants. Moreover, root development was only slightly affected by the ectopic expression of the transgene. Reactive oxygen species were accumulated to a lower extent in leaf tissues of multi-auto-transformation (MAT)-PsMT_A1 plants exposed to copper and zinc, compared to control plants. Tolerance to photo-oxidative stress induced by paraquat was another distinctive feature of the MAT-PsMT_A1 lines. Finally, low levels of DNA damage were detected by quantifying the amounts of 8-hydroxy-2′-deoxyguanosine in leaf tissues of the transgenic plants exposed to copper.     

Recovery of useful traits from isolates inhabiting an agricultural soil cultivated with herbicide-resistant poplars

The aim of this study was to investigate the culturable bacteria living in soil cultivated with Basta-tolerant transgenic white poplars (Populus alba L. 'Villafranca'). Plate Count Agar medium containing phosphinothricin, the active component of Basta, was used to isolate the herbicide-resistant bacteria (HRB). No significant changes in the size of the soil microbial flora following herbicide treatment were observed. The characterization of HRB isolates by 16S rDNA-based taxonomy revealed a predominance of Pseudomonas and Bacillus species. The screening carried out on soil samples allowed for the recovery of isolates with useful properties for biotechnological and agronomical purposes, particularly in relation to root development. Among the tested isolates, only HRB-1b, HRB-1c, and HRB-7 showed remarkable swarming ability, a valuable trait supporting the beneficial plant-microbe interactions. HRB-1c was also characterized by consistent production of indoleacetic acid (17.8 +/- 0.09 microg x mL-1 x (OD600 unit)-1), and it was able to stimulate the in vitro growth of Villafranca explants. Since novel tools are constantly required to enhance productivity of perennial species and to expand their use for practical purposes, the availability of bacteria that support tree growth, such as the HRB-1c isolate, represents a significant advantage.     

Evaluation of MAT-vector system in white poplar (<Emphasis Type="Italic">Populus alba</Emphasis> L.) and production of <Emphasis Type="Italic">ipt</Emphasis> marker-free transgenic plants by ‘single-step transformation’

Genetic transformation of an elite white poplar genotype (Populus alba L., cv. ‘Villafranca’) was performed with MAT vectors carrying the ipt and rol genes from Agrobacterium spp. as morphological markers. The effects associated with the use of different gene promoters and distinct in vitro regeneration protocols were evaluated. Poplar plantlets showing abnormal ipt and rol phenotypes were produced only in the presence of exogenous growth regulators. The occurrence of abnormal ipt and rol phenotypes allowed the visual selection of transformants. The ipt-type MAT vector pEXM2 was used to monitor the activity of the yeast site-specific recombination R/RS system in the transformed white poplar cells. Results from these experiments demonstrated that recombinase-mediated excision events occurred during the early stages of in vitro culture, thus causing the direct production of ipt marker-free transgenic plants with normal phenotype at an estimated frequency of 36.4%. Beside this unexpected finding, transgenic ipt-shooty plants were obtained at a frequency of 63.6% and normal shoots were subsequently recovered after a prolonged period of in vitro culture. Although the transformation efficiency observed in this study, using both ipt and nptII genes as selection markers, was similar to that previously reported with standard vectors carrying only the nptII gene, the easy identification of ipt transformants, the early recombinase-mediated excision events and finally the relatively short time period required to produce ipt marker-free transgenic plants support for the choice of MAT vectors as a reliable strategy for the future production of marker-free GM poplars.