Marcin Filipecki

Unintended consequences of plant transformation: a molecular insight.

Plant genomes are dynamic structures having both the system to maintain and accurately reproduce the information encoded therein and the ability to accept more or less random changes, which is one of the foundations of evolution. Crop improvement and various uncontrolled stress factors can induce unintended genetic and epigenetic variations. In this review it is attempted to summarize factors causing such changes and the molecular nature of these variations in transgenic plants. Unintended effects in transgenic plants can be divided into three main groups: first, pleiotropic effects of integrated DNA on the host plant genome; second, the influence of the integration site and transgene architecture on transgene expression level and stability; and third, the effect of various stresses related to tissue handling, regeneration and clonal propagation. Many of these factors are recently being redefined due to new researches, which apply modern highly sensitive analytical techniques and sequenced model organisms. The ability to inspect large portions of genomes clearly shows that tissue culture contributes to a vast majority of observed genetic and epigenetic changes. Nevertheless, monitoring of thousands transcripts, proteins and metabolites reveals that unintended variation most often falls in the range of natural differences between landraces or varieties. We expect that an increasing amount of evidence on many important crop species will support these observations in the nearest future.

Characterization of CsSEF1 gene encoding putative CCCH-type zinc finger protein expressed during cucumber somatic embryogenesis.

Somatic embryos obtained in vitro are a form of vegetative reproduction that can be used in artificial seed technology, as well as a model to study the principles of plant development. In order to isolate the genes involved in somatic embryogenesis of the cucumber (Cucumis sativus L.), we utilized the suppression subtractive hybridization (SSH). One of the obtained sequences was the CsSEF1 clone (Cucumis sativus Somatic Embryogenesis Zinc Finger 1), with a level of expression that sharply increased with the induction of embryogenesis. The full length cDNA of CsSEF1 encodes the putative 307 amino acid long protein containing three zinc finger motifs, two with CCCH and one with the atypical CHCH pattern. The CsSEF1 protein shows significant similarity to other proteins from plants, in which the zinc fingers arrangement and patterns are very similar. Transcripts of CsSEF1 were localized in the apical part of somatic embryos, starting as early as the polarity was visible and in later developmental stages marking the cotyledon primordia and procambium tissues. As a result of transferring an antisense fragment of CsSEF1 into Arabidopsis thaliana abnormalities in zygotic embryos and also in cotyledons and root development were observed.

Dynamics in the tomato root transcriptome on infection with the potato cyst nematode Globodera rostochiensis

Plant parasitic nematodes infect roots and trigger the formation of specialized feeding sites by substantial reprogramming of the developmental process of root cells. In this article, we describe the dynamic changes in the tomato root transcriptome during early interactions with the potato cyst nematode Globodera rostochiensis. Using amplified fragment length polymorphism-based mRNA fingerprinting (cDNA-AFLP), we monitored 17 600 transcript-derived fragments (TDFs) in infected and uninfected tomato roots, 1-14 days after inoculation with nematode larvae. Six hundred and twenty-four TDFs (3.5%) showed significant differential expression on nematode infection. We employed GenEST, a computer program which links gene expression profiles generated by cDNA-AFLP and databases of cDNA sequences, to identify 135 tomato sequences. These sequences were grouped into eight functional categories based on the presence of genes involved in hormone regulation, plant pathogen defence response, cell cycle and cytoskeleton regulation, cell wall modification, cellular signalling, transcriptional regulation, primary metabolism and allocation. The presence of unclassified genes was also taken into consideration. This article describes the responsiveness of numerous tomato genes hitherto uncharacterized during infection with endoparasitic cyst nematodes. The analysis of transcriptome profiles allowed the sequential order of expression to be dissected for many groups of genes and the genes to be connected with the biological processes involved in compatible interactions between the plant and nematode.

The MADS-box gene CUS1 is expressed during cucumber somatic embryogenesis

Abstract We report the isolation and characterisation of cDNA and genomic clones of a MADS-box gene which is expressed in cucumber fruit and somatic embryos. The cDNA clone was isolated using a heterologous probe, MADS-box cDNA fragments from Antirrhinum majus. The CUS1 cDNA clone was sequenced and the deduced amino acid sequence is highly similar to the products of the the PLENA gene from Antirrhinum majus, of the FBP6 gene from Petunia hybrida and of the AGL1 and AGL5 genes from Arabidopsis thaliana. The presence of single copy of CUS1 and a family of related genes in the cucumber genome was demonstrated by Southern blots. The 1050 bases long CUS1 transcript was only detected in embryogenic callus, in fruit and weakly in female flowers, and was absent in non-embryogenic callus and other organs of the seedling and mature plant. More specifically the CUS1 transcript was detected only in the outer cell layers of the radicular part of the heart stage somatic embryo, in transmitting tissue of female flowers and in tissues surrounding the ovules. The structure of the CUS1 gene was determined.

Identification of genes up-regulated during somatic embryogenesis of cucumber

Somatic embryogenesis is a method of plant regeneration, but it can also be used as a model to study plant development. A normalized library of cDNA fragments representing genes up-regulated after the induction of somatic embryogenesis in cucumber suspension cultures was constructed using the suppression subtractive hybridization technique. Candidate cDNA fragments (119) were classified according to their similarity to genes encoding known proteins and the presence of potential functional domains. Of the translation products with homology to known proteins, about 23% were possibly involved in metabolism, 13% represented proteins with a probable role in cellular communication and signal transduction, about 12% were likely to participate in protein synthesis, while around 10% were potential transcription factors. The genes corresponding to four of the cDNAs were subsequently analyzed in more detail: CsSEF2, CsSEM1 and CsSESTK1 encoding putative transcription factors or co-activators, and CsSECAD1 encoding cinnamyl alcohol dehydrogenase. Full-length cDNAs were isolated and analyzed. RT-PCR confirmed the up-regulation of these genes after the induction of somatic embryogenesis and showed the presence of their transcripts in other tissues. The in situ localization of transcripts of the CsSEF2 and CsSEM1 genes demonstrated that signalling in somatic embryo tissues involving these factors is concentrated in the cotyledon primordia and roots.

The heritable changes in metabolic profiles of plants regenerated in different types of in vitro culture

In this work we show how three types of cucumber in vitro cultures – leaf callus culture, cytokinin dependent cell suspension and liquid culture of meristematic clumps – influence the metabolite profiles of plants in the first generative progeny. Based on this study we conclude that there exists a specific and inheritable metabolic fingerprint reflecting the history of previous generations, probably related to specific stress factors accompanying the passage through different types of culture. The leaf callus culture generated the highest heritable differences in metabolite content and was the most distinctly separated cluster in PCA analysis. The smallest number of variable metabolites characterizes the plants regenerated from cytokinin dependent cell suspension whereas the liquid culture of meristematic clumps induced slightly more changes. Changes induced by these two culture types were not as pronounced as in the case of leaf callus culture. However the plants after these types of culture were well separated from the control on PCA diagram. The highest changes were over 2-fold increases in cystin and galactose-6-P and over 2-fold decreases in aspartate, myo-inositol, hydroxylamine, phosphate and putrescine. These changes concerned the plants, which were one generation after the leaf callus culture. The possible nature of observed heritable changes is discussed.

Infiltration with Agrobacterium - the method for stable transformation avoiding tissue culture

A number of in planta transformation protocols that avoid long culture under sterile conditions were developed for Arabidopsis thaliana. The most widely used methods are based on vacuum infiltration and floral dip. These methods were adapted for transformation of other species as well. Successful in planta transformations of alfalfa, radish, pakchoi and petunia were reported recently. In this short review we present several modified procedures originally developed for Arabidopsis thaliana and in some cases adapted to other species. We emphasize the crucial parameters involved in in planta transformation. We also describe here the studies attempting to shed light on the mechanisms and estimating the cellular target of transformation, which may help in transforming new plant species.

Tissue-culture-responsive and autotetraploidy-responsive changes in metabolic profiles of cucumber (Cucumis sativus L.)

Somaclonal variation commonly occurs duringin vitro plant regeneration and may introduce unintended changes in numerous plant characters. In order to assess the range of tissue-culture-responsive changes on the biochemical level, the metabolic profiles of diploid and tetraploid cucumber R1 plants regenerated from leaf-derived callus were determined. Gas chromatography and mass spectrometry were used for monitoring of 48 metabolites and many significant changes were found in metabolic profiles of these plants as compared to a seed-derived control. Most of the changes were common to diploids and tetraploids and were effects of tissue culture. However, tetraploids showed quantitative changes in 14 metabolites, as compared to regenerated diploids. These changes include increases in serine, glucose-6P, fructose-6P, oleic acid and shikimic acid levels. Basing on this study we conclude that the variation in metabolic profiles does not correlate directly with the range of genome changes in tetraploids.

Molecular characterization of SCARECROW (CsSCR) gene expressed during somatic embryo development and in root of cucumber (Cucumis sativus L.)

Somatic embryogenesis (SE) in plants can be used as a model for studying genes engaged in the embryogenic transition of somatic cells. The CsSCARECROW (CsSCR) gene was previously identified among a panel of genes upregulated after the induction of SE in cucumber (Cucumis sativus). The putative CsSCR protein contains conserved GRAS family domains and is extremely similar to AtSCR from Arabidopsis thaliana. SCR proteins are transcription factors involved in root radial patterning and are required for maintenance of the quiescent centre and differentiation of the endodermis. In comparison with other GRAS proteins from cucumber, phylogenetic analyses showed that CsSCR belongs to the SCR cluster. Increased CsSCR transcript accumulation was detected in somatic embryos and roots. Southern blot analysis and screening of the draft version of the cucumber genome confirmed the lack of close homologues in this species. CsSCR transcripts were localized by in situ hybridization in undifferentiated cells in the globular and heart stages of somatic embryogenesis, and in the endodermis of torpedo and cotyledonary stage somatic embryos, and developing primary and lateral roots. This localization was supported by the pattern of reporter gene activity driven by the CsSCR promoter in transgenic cucumber organs. These results suggest that CsSCR is likely to act in tissue radial organization during somatic embryogenesis and root development.

Analysis of tomato gene promoters activated in syncytia induced in tomato and potato hairy roots by Globodera rostochiensis

The potato cyst nematode (Globodera rostochiensis) induces feeding sites (syncytia) in tomato and potato roots. In a previous study, 135 tomato genes up-regulated during G. rostochiensis migration and syncytium development were identified. Five genes (CYP97A29, DFR, FLS, NIK and PMEI) were chosen for further study to examine their roles in plant–nematode interactions. The promoters of these genes were isolated and potential cis regulatory elements in their sequences were characterized using bioinformatics tools. Promoter fusions with the β-glucuronidase gene were constructed and introduced into tomato and potato genomes via transformation with Agrobacterium rhizogenes to produce hairy roots. The analysed promoters displayed different activity patterns in nematode-infected and uninfected transgenic hairy roots.