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To further improve antibody production in plants, constructs were designed to minimize transgene silencing and to retain a F(ab) fragment within the secretory pathway of transgenic Arabidopsis thaliana plants. The levels of antibody accumulation suggest that placing the sequences that encode Fd and light chain under the control of nonidentical 3' regions reduces susceptibility to post-transcriptional gene silencing compared with when the individual polypeptide-encoding sequences are placed under the control of identical 3' regions. High levels of accumulation (up to 6% of total soluble protein) were found for both secreted and intracellularly targeted antibody fragments. Immunofluorescence microscopic analysis showed that F(ab) fragments devoid of any additional C-terminal sequence were efficiently secreted, whereas retention of F(ab) fragments within the endomembrane system of the secretory pathway was achieved by C-terminal fusion of the DIKDEL sequence to the antibody light chain. Furthermore, analysis by immunoprecipitation and ELISA showed that intracellular retention of antibody fragments did not affect antigen-binding activity, and more than 80% of the isolated antibody fragments were found to bind antigen. Taken together, our results provide improvements to the technology of recombinant antibody production in transgenic plants.

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The stability of Fab antibody fragment expression during plant development was studied using two homozygous Arabidopsis thaliana lines that contain single copies of the transgenes. These lines exhibited expression characteristics that are typical for homology-based post-transcriptional gene silencing. Their developmental silencing profiles differed markedly, presumably due to the influence of the genomic context on the T-DNAs. In both lines, a clear gene dosage effect could be observed: in contrast to the homozygous lines, derived hemizygous plants accumulated high levels of Fab fragments throughout development. Interestingly, silencing also occurred in double-hemizygous plants, which resulted from a cross between the two homozygous lines and had two copies of each T-DNA at non-allelic positions in their genome. In all cases, down-regulation of the Fab levels was strictly correlated with methylation of cytosine residues in the transcribed regions of the transgenes. Remarkably, this methylation was also found in regions in which the transgenes were non-homologous regions. Finally, the time point of down-regulation depended on the culture conditions and differed for leaves and roots of the same transgenic plant.

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Our current knowledge allows the generation of transgenic plants that efficiently produce heterologous proteins from plant, bacterial, fungal or animal origin. Among all types of recombinant proteins, antibodies are particularly attractive because of their ability to specifically recognize and bind virtually any type of antigen. Plants show several advantages as a large-scale antibody production system: they can be grown easily and inexpensively in large quantities that can be harvested, stored and processed by using existing infrastructures. Isolation and purification of plant-made antibodies, if necessary, allow fundamental, industrial, and therapeutical applications. In the past, we and others have successfully generated antibody-producing plants. The maximal accumulation levels of antibodies and antibody fragments that we observed are 1-5% of the extracted proteins. Currently, several biotechnological companies grow field crops to produce antibodies for ex planta applications on an industrial scale.

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Immunomodulation is a molecular technique that allows the interference with cellular metabolism or pathogen infectivity by the ectopic expression of genes encoding antibodies or antibody fragments. In recent years, several reports have proven the value of this tool in plant research for modulation of phytohormone activity and for blocking plant-pathogen infection. Efficient application of the plantibody approach requires different levels of investigation. First of all, methods have to be available to clone efficiently the genes coding for antibodies or antibody fragments that bind the target antigen. Secondly, conditions to obtain high accumulation of antigen-binding antibodies and antibody fragments in plants are being investigated and optimized. Thirdly, different strategies are being evaluated to interfere with the function of the target molecule, thus enabling immunomodulation of metabolism or pathogen infectivity. In the near future, optimized antibody gene isolation and expression, especially in reducing subcellular environments, such as the cytosol and nucleus, should turn immunomodulation into a powerful and attractive tool for gene inactivation, complementary to the classical antisense and co-suppression approaches.

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Plants are particularly attractive as large-scale production systems for proteins intended for therapeutical or industrial applications: they can be grown easily and inexpensively in large quantities that can be harvested and processed with the available agronomic infrastructures. The effective use of plants as bioreactors depends on the possibility of obtaining high protein accumulation levels that are stable during the life cycle of the transgenic plant and in subsequent generations. Silencing of the introduced transgenes has frequently been observed in plants, constituting a major commercial risk and hampering the general economic exploitation of plants as protein factories. Until now, the most efficient strategy to avoid transgene silencing involves careful design of the transgene construct and thorough analysis of transformants at the molecular level. Here, we focus on different aspects of the generation of transgenic plants intended for protein production and on their influence on the stability of heterologous gene expression.

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Using the Cre/lox recombination system, we analyzed the extent to which T-DNA transfer to the plant cell and T-DNA integration into the plant genome determine the transformation and cotransformation frequencies of Arabidopsis root cells. Without selection for transformation competence, the stable transformation frequency of shoots obtained after cocultivation and regeneration on nonselective medium is below 0.5%. T-DNA transfer and expression occur in 5% of the shoots, indicating that the T-DNA integrates in less than 10% of the transiently expressing plant cells. A limited fraction of root cells, predominantly located at the wounded sites and in the pericycle, are competent for interaction with agrobacteria and the uptake of a T-DNA, as demonstrated by histochemical GUS staining. When selection for transformation competence is applied, the picture is completely different. Then, approximately 50% of the transformants show transient expression of a second, nonselected T-DNA and almost 50% of these cotransferred T-DNAs are integrated into the plant genome. Our results indicate that both T-DNA transfer and T-DNA integration limit the transformation and cotransformation frequencies and that plant cell competence for transformation is based on these two factors.

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The stability of antibody and Fab expression was assessed in five different homozygous transgenic Arabidopsis lines. Each of these lines showed silencing of the transgenes that encode the antibody polypeptides, leading to instability of antibody production. However, each line had a different and specific instability profile. The characteristic variation in the level of antibody accumulation in each line as a function of developmental stage indicated that the T-DNA integration pattern played a role in triggering silencing, and also that the history and the integration position of simple transgene loci can influence the susceptibility to epigenetic silencing. In different lines with low antibody accumulation levels, methylation was found either in the promoter alone, in both the promoter and the transcribed region, in the transcribed region only, or in the transcribed region and downstream sequences. In conclusion, our data suggest that epigenetic effects result in different transgene expression profiles in each of the five Arabidopsis lines analyzed.

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The accumulation of five murine single-chain variable fragments, binding to dihydroflavonol 4-reductase, was analyzed in transgenic Petunia hybrida plants. The five scFv-encoding sequences were cloned in an optimized plant transformation vector for expression in the cytosol under control of the 35S promoter. In a transient expression assay we found that the scFv expression levels were reproducible and correlated with those in stably transformed petunia. Our results show that accumulation in the cytosol strongly depends on the intrinsic properties of the scFv fragment. Three of the five scFv fragments accumulated to unexpectedly high levels in the cytosol of the primary transformants, but no phenotypic effect could be detected. Experimental results indicate that one of the scFv fragments accumulated in the cytosol to 1% of the total soluble protein as a functional antigen-binding protein in the absence of disulphide bonds. This observation supports the idea that certain antibody fragments do not need disulphide bonds to be stable and functional. Such scFv scaffolds provide new opportunities to design scFv fragments for immunomodulation in the cytosol.

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For the further optimization of antibody expression in plants, it is essential to determine the final accumulation sites of plant-made antibodies. Previously, we have shown that, upon secretion, IgG antibodies and Fab fragments can be detected in the intercellular spaces of leaf mesophyll cells of transgenic Arabidopsis thaliana plants. However, immunofluorescence microscopy showed that this is probably not their final accumulation site. In leaves, IgG and Fab fragments accumulate also at the interior side of the epidermal cell layers and in xylem vessels. These accumulation sites correspond with the leaf regions where water of the transpiration stream is entering a space impermeable to the proteins or where water is evaporating. In roots, plant-made Fab fragments accumulate in intercellular spaces of cortex cells, in the cytoplasm of pericycle and, to a lesser extent, endodermis cells, and in cells of the vascular cylinder. In other words, antibody accumulation occurs at the sites where water passes on its radial pathway towards and within the vascular bundle. Taken together, our results suggest that, upon secretion of plant-made antibodies or Fab fragments, a large proportion of these proteins are transported in the apoplast of A. thaliana, possibly by the water flow in the transpiration stream.

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To isolate specific single-chain variable (scFv) fragments against dihydroflavonol 4-reductase (DFR) from Petunia hybrida the phage display technology was used. DFR was overproduced in Escherichia coli, purified and used for immunization. From DFR-immunized mice, a phage display library was made starting from spleen mRNA using an optimized set of primers for V(H) and V(L) amplification. Several rounds of panning against recombinant DFR yielded five different scFv fragments, confirmed by subsequent DNA sequencing. They all specifically bound to recombinant DFR in ELISA and DFR in flower extracts on Western blot. These results show that phage display is a promising technology in plant molecular biology to obtain specific recombinant antibodies not only for ELISA and Western blot but also for in vivo applications in the long run.

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A gene encoding a single-chain variable (scFv) antibody fragment was expressed as a cytoplasmic and endoplasmic reticulum-targeted protein in transgenic tobacco plants. In both cases, the scFv accumulated up to 0.01% of total soluble protein (TSP). The same scFv fragment was also produced in the periplasm of Escherichia coli. Measurement of the affinity by ELISA indicates that the affinity of the bacterially made scFv is about 80-fold lower than that of the parental Fab fragment. The results suggest that the affinity of the plant-produced scFv fragments is reduced to a similar extent, implying that all the plant-produced scFv fragments are antigen binding.

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