Frequencies of simultaneous transformation with different T-DNAs and their relevance to the Agrobacterium/plant cell interaction

Summary We investigated whether the efficiency of transformation of plant cells by Agrobacterium tumefaciens during cocultivation is limited by the properties of the plant cells or by the infecting bacteria.Therefore, tobacco protoplasts were infected by cocultivation with two different agrobacteria strains carrying Ti plasmids with distinguishable T-DNAs. These T-DNAs cotransform plant cells at a frequency equal to the product of their independent transformation frequencies, which indicates that all plant cells are equally competent. On the other hand, when these T-DNAs are located on the same Ti plasmid vector within one bacterial strain, the cotransformation frequency is significantly higher than the product of the single transformation frequencies. We interpret these results to indicate that transformation is limited more by the establishment of effective bacteria/plant cell interaction than by (i) the process of DNA integration and (ii) by the number of plant cells capable of being transformed by Agrobacterium. We found that most plant cells are transformed by only one or a few agrobacteria. Analysis of the number of T-DNA copies in these clonally transformed lines indicates amplification of the original, infecting T-region copy.     

Base Excision Repair and its Role in Maintaining Genome Stability

For all living organisms, genome stability is important, but is also under constant threat because various environmental and endogenous damaging agents can modify the structural properties of DNA bases. As a defense, organisms have developed different DNA repair pathways. Base excision repair (BER) is the predominant pathway for coping with a broad range of small lesions resulting from oxidation, alkylation, and deamination, which modify individual bases without large effect on the double helix structure. As, in mammalian cells, this damage is estimated to account daily for 10⁴ events per cell, the need for BER pathways is unquestionable. The damage-specific removal is carried out by a considerable group of enzymes, designated as DNA glycosylases. Each DNA glycosylase has its unique specificity and many of them are ubiquitous in microorganisms, mammals, and plants. Here, we review the importance of the BER pathway and we focus on the different roles of DNA glycosylases in various organisms.     

Site‐specific T–DNA integration in Arabidopsis thaliana mediated by the combined action of CRE recombinase and ϕC31 integrase

Random T–DNA integration into the plant host genome can be problematic for a variety of reasons, including potentially variable transgene expression as a result of different integration positions and multiple T–DNA copies, the risk of mutating the host genome and the difficulty of stacking well‐defined traits. Therefore, recombination systems have been proposed to integrate the T–DNA at a pre‐selected site in the host genome. Here, we demonstrate the capacity of the ?C31 integrase (INT) for efficient targeted T–DNA integration. Moreover, we show that the iterative site‐specific integration system (ISSI), which combines the activities of the CRE recombinase and INT, enables the targeting of genes to a pre‐selected site with the concomitant removal of the resident selectable marker. To begin, plants expressing both the CRE and INT recombinase and containing the target attP site were constructed. These plants were supertransformed with a T–DNA vector harboring the loxP site, the attB sites, a selectable marker and an expression cassette encoding a reporter protein. Three out of the 35 transformants obtained (9%) showed transgenerational site‐specific integration (SSI) of this T–DNA and removal of the resident selectable marker, as demonstrated by PCR, Southern blot and segregation analysis. In conclusion, our results show the applicability of the ISSI system for precise and targeted Agrobacterium‐mediated integration, allowing the serial integration of transgenic DNA sequences in plants.     

Biomanufacturing of protective antibodies and other therapeutics in edible plant tissues for oral applications

Although plant expression systems used for production of therapeutic proteins have the advantage of being scalable at a low price, the downstream processing necessary to obtain pure therapeutic molecules is as expensive as for the traditional Chinese hamster ovary (CHO) platforms. However, when edible plant tissues (EPTs) are used, there is no need for exhaustive purification, because they can be delivered orally as partially purified formulations that are safe for consumption. This economic benefit is especially interesting when high doses of recombinant proteins are required throughout the treatment/prophylaxis period, as is the case for antibodies used for oral passive immunization (OPI). The secretory IgA (SIgA) antibodies, which are highly abundant in the digestive tract and mucosal secretions, and thus the first choice for OPI, have only been successfully produced in plant expression systems. Here, we cover most of the up‐to‐date examples of EPT‐produced pharmaceuticals, including two examples of SIgA aimed at oral delivery. We describe the benefits and drawbacks of delivering partially purified formulations and discuss a number of practical considerations and criteria to take into account when using plant expression systems, such as subcellular targeting, protein degradation, glycosylation patterns and downstream strategies, all crucial for improved yield, high quality and low cost of the final product.     

The preferred route for the degradation of silencing target RNAs in transgenic plants depends on pre-established silencing conditions

RNA silencing can be initiated upon dsRNA accumulation and results in homology-dependent degradation of target RNAs mediated by 21–23 nt small interfering RNAs (siRNAs). These small regulatory RNAs can direct RNA degradation via different routes such as the RdRP/Dicer- and the RNA-induced silencing complex (RISC)-catalysed pathways. The relative contribution of both pathways to degradation of target RNAs is not understood. To gain further insight in the process of target selection and degradation, we analysed production of siRNAs characteristic for Dicer-mediated RNA degradation during silencing of mRNAs and chimeric viral RNAs in protoplasts from plants of a transgenic tobacco silencing model line. We show that small RNA accumulation is limited to silencing target regions during steady-state mRNA silencing. For chimeric viral RNAs, siRNA production appears dependent on pre-established cellular silencing conditions. The observed siRNA accumulation profiles imply that silencing of viral target RNAs in pre-silenced protoplasts occurs mainly via a RISC-mediated pathway, guided by (pre-existing) siRNAs derived from cellular mRNAs. In cells that are not silenced at the time of infection, viral RNA degradation seems to involve Dicer action directly on the viral RNAs. This suggests that the silencing mechanism flexibly deploys different components of the RNA degradation machinery in function of the prevailing silencing status.     

Disruption of their palindromic arrangement leads to selective loss of DNA methylation in inversely repeated<Emphasis Type="Italic"> gus</Emphasis> transgenes in Arabidopsis

The transgene locus KH15, which is highly susceptible to silencing in Arabidopsis thaliana, contains two inversely repeated beta-glucuronidase (gus) genes separated by a palindromic sequence and has a low GUS activity, was found to be heavily methylated in the gus coding sequence and in the center of the inverted repeat. The locus KHsb67, which is less prone to silencing, was found to be less densely methylated in the non-repetitive region that separates the inversely repeated gus genes. After the removal of one of the gus genes by Cre-mediated recombination, methylation in both loci decreased or was totally lost. Despite the presence of a 732-bp palindromic sequence in the deletion line derived from KH15, this sequence was not methylated. Whereas the KH15 locus triggers methylation of homologous gus genes when placed in trans to them, the deletion derivative did not, suggesting that the capacity for cross-talk was severely affected by disruption of the palindromic arrangement. This result suggests that the transcribed palindromic sequences are required to maintain the methylation of both symmetrically and non-symmetrically arranged cytosines.     

Analysis of the interaction between single-chain variable fragments and their antigen in a reducing intracellular environment using the two-hybrid system

The coding sequences of three single-chain variable (scFv) fragments (A4, G4 and H3), which bind to dihydroflavonol-4-reductase (DFR) of Petunia hybrida, and the DFR-encoding sequence were cloned in two-hybrid vectors. The vectors were transformed in the yeast strain HF7c (his3-200, trp1-901, leu2-3) and the scFv-DFR interaction was analyzed by measuring yeast growth on medium without histidine. ScFv-G4 and, to a lesser extent, scFv-A4 could interact with DFR in the yeast nucleus. On the contrary, scFv-H3 showed no interaction with its antigen in yeast. The results of a previous expression analysis of the same scFv fragments in the plant cytosol correlate with those of the two-hybrid test. This suggests that it is possible to evaluate the antigen-scFv interaction in a reducing subcellular environment with the two-hybrid test. Therefore, the yeast two-hybrid system can be useful to identify candidate scFv fragments for intracellular antibody applications.