Recombination products suggest the frequent occurrence of aberrant gene replacement in the moss Physcomitrella patens.

In gene replacement, a variant of gene targeting, transformed DNA integrates into the genome by homologous recombination (HR) to replace resident sequences. Gene replacement in the moss Physcomitrella patens is extremely efficient, but often large amounts of additional DNA are integrated at the target locus. A detailed analysis of recombination junctions of PpCOL2 gene knockout mutants shows that the integrated DNA can be highly rearranged. Our data suggest that the replaced sequences were excised by HR and became integrated back into the genome by non-homologous end-joining (NHEJ). RAD51-mediated strand-invasion and subsequent strand-exchange is central to the two-end invasion pathway, the major gene replacement pathway in yeast. In this pathway, integration is initiated by the free ends of a single replacement vector-derived donor molecule which then integrates as an entity. Gene replacement in P. patens is entirely RAD51-dependent suggesting the existence of a pathway mechanistically similar to two-end invasion. However, invasion of the two ends does not seem to be stringently coordinated in P. patens. Actually, often only one fragment end became integrated by HR, or one-sided integration of two independent donor fragments occurred simultaneously leading to a double-strand break that is subsequently sealed by NHEJ and thus causes the observed rearrangements.

Comparison of the MpEF1α and CaMV35 promoters for application in Marchantia polymorpha overexpression studies.

Constitutive promoters are essential tools for analyses of gene functions by transgenic approaches. For overexpression and silencing studies of genes, a ubiquitous and strong expression of genes under investigation as well as selection markers is preferred. For future applications in the emerging basal plant model system Marchantia polymorpha, a liverwort, activities of the viral 35S cauliflower mosaic virus promoter and the endogenous elongation factor 1α (MpEF1α) promoter were analyzed. Expression of the reporter gene ß-glucuronidase (GUS), driven by the CaMV35 and MpEF1α promoters, was compared throughout plant development. Significant differences were observed between the two promoter activities. The CaMV35 promoter yields a weak reporter gene expression in the meristematic zones but drives a strong expression in the thallus. The MpEF1α promoter causes a strong meristematic GUS expression and is more active in female sexual tissues. Overall, the MpEF1α promoter seems to be the better option for obtaining a strong and ubiquitous transgene expression. Furthermore, a whole mount in situ hybridization protocol for Marchantia was established. Analysis of MpEF1α mRNA transcript in intact, whole tissues showed an expression pattern that is overall similar to the pattern of the GUS reporter gene expression driven by the MpEF1α promoter, including strong expression in meristematic zones. The whole mount technique reported here can be used to determine the mRNA expression in intact gemmae and archegonia, and has the potential to be applied for screening large numbers of transgenic plants, for instance to identify knock-down mutants.

MIKC* MADS-box proteins: conserved regulators of the gametophytic generation of land plants.

Land plants (embryophytes) are characterized by an alternation of two generations, the haploid gametophyte and the diploid sporophyte. The development of the small and simple male gametophyte of the flowering plant Arabidopsis (Arabidopsis thaliana) critically depends on the action of five MIKC* group MCM1-AGAMOUS-DEFICIENS-SRF-box (MADS-box) proteins. In this study, these MIKC* MADS-box genes were isolated from land plants with relatively large and complex gametophyte bodies, namely the bryophytes. We found that although the gene family expanded in the mosses Sphagnum subsecundum, Physcomitrella patens, and Funaria hygrometrica, only a single homologue, Marchantia polymorpha MADS-box gene 1 (MpMADS1), has been retained in the liverwort M. polymorpha. Liverworts are the earliest diverging land plants, and so a comparison of MpMADS1 with its angiosperm homologues addresses the molecular evolution of an embryophyte-specific transcription factor over the widest phylogenetic distance. MpMADS1 was found to form a homodimeric DNA-binding complex, which is in contrast to the Arabidopsis proteins that are functional only as heterodimeric complexes. The M. polymorpha homodimer, nevertheless, recognizes the same DNA sequences as its angiosperm counterparts and can functionally replace endogenous MIKC* complexes to a significant extent when heterologously expressed in Arabidopsis pollen. The 11 MIKC* homologues from the moss F. hygrometrica are highly and almost exclusively expressed in the gametophytic generation. Taken together, these findings suggest that MIKC* MADS-box proteins have largely preserved molecular roles in the gametophytic generation of land plants.

SBP-domain transcription factors as possible effectors of cryptochrome-mediated blue light signalling in the moss Physcomitrella patens.

Cryptochromes are blue light absorbing photoreceptors found in many organisms and involved in numerous developmental processes. At least two highly similar cryptochromes are known to affect branching during gametophytic development in the moss Physcomitrella patens. We uncovered a relationship between these cryptochromes and the expression of particular members of the SBP-box genes, a plant specific transcription factor family. Transcript levels of the respective moss SBP-box genes, all belonging to the LG1-subfamily, were found to be dependent, albeit not exclusively, on blue light. Moreover, disruptant lines generated for two moss representatives of this SBP-box gene subfamily, both showed enhanced caulonema side branch formation, a phenotype opposite to that of the ppcry1a/1b double disruptant line. In this report we show that PpCRY1a and PpCRY1b act negatively on the transcript levels of several related moss SBP-box genes and that at least PpSBP1 and PpSBP4 act as negative regulators of side branch formation.

Differential requirements for RAD51 in Physcomitrella patens and Arabidopsis thaliana development and DNA damage repair.

RAD51, the eukaryotic homolog of the bacterial RecA recombinase, plays a central role in homologous recombination (HR) in yeast and animals. Loss of RAD51 function causes lethality in vertebrates but not in other animals or in the flowering plant Arabidopsis thaliana, suggesting that RAD51 is vital for highly developed organisms but not for others. Here, we found that loss of RAD51 function in the moss Physcomitrella patens, a plant of less complexity, caused a significant vegetative phenotype, indicating an important function for RAD51 in this organism. Moreover, loss of RAD51 caused marked hypersensitivity to the double-strand break-inducing agent bleomycin in P. patens but not in Arabidopsis. Therefore, HR is used for somatic DNA damage repair in P. patens but not in Arabidopsis. These data imply fundamental differences in the use of recombination pathways between plants. Moreover, these data demonstrate that the importance of RAD51 for viability is independent of taxonomic position or complexity of an organism. The involvement of HR in DNA damage repair in the slowly evolving species P. patens but not in fast-evolving Arabidopsis suggests that the choice of the recombination pathway is related to the speed of evolution in plants.

Boosting heterologous protein production in transgenic dicotyledonous seeds using Phaseolus vulgaris regulatory sequences.

Over the past decade, several high value proteins have been produced in different transgenic plant tissues such as leaves, tubers, and seeds. Despite recent advances, many heterologous proteins accumulate to low concentrations, and the optimization of expression cassettes to make in planta production and purification economically feasible remains critical. Here, the regulatory sequences of the seed storage protein gene arcelin 5-I (arc5-I) of common bean (Phaseolus vulgaris) were evaluated for producing heterologous proteins in dicotyledonous seeds. The murine single chain variable fragment (scFv) G4 (ref. 4) was chosen as model protein because of the current industrial interest in producing antibodies and derived fragments in crops. In transgenic Arabidopsis thaliana seed stocks, the scFv under control of the 35S promoter of the cauliflower mosaic virus (CaMV) accumulated to approximately 1% of total soluble protein (TSP). However, a set of seed storage promoter constructs boosted the scFv accumulation to exceptionally high concentrations, reaching no less than 36.5% of TSP in homozygous seeds. Even at these high concentrations, the scFv proteins had antigen-binding activity and affinity similar to those produced in Escherichia coli. The feasibility of heterologous protein production under control of arc5-I regulatory sequences was also demonstrated in Phaseolus acutifolius, a promising crop for large scale production.