Attila Fehér

Transition of somatic plant cells to an embryogenic state

Under appropriate in vivo or in vitro conditions, certain somatic plant cells have the capability to initiate embryogenic development (somatic embryogenesis). Somatic embryogenesis provides an unique experimental model to understand the molecular and cellular bases of developmental plasticity in plants. In the last few years, the application of modern experimental techniques, as well as the characterization of Arabidopsis embryogenesis mutants, have resulted in the accumulation of novel data about the acquisition of embryogenic capabilities by somatic plant cells. In this review, we summarize relevant experimental observations that can contribute to the description and definition of a transitional state of somatic cells induced to form totipotent, embryogenic cells. During this somatic-to-embryogenic transition, cells have to dedifferentiate, activate their cell division cycle and reorganize their physiology, metabolism and gene expression patterns. The roles of stress, endogenous growth regulators and chromatin remodelling in the coordinated reorganization of the cellular state are especially emphasized.

The Role of Auxin, pH, and Stress in the Activation of Embryogenic Cell Division in Leaf Protoplast-Derived Cells of Alfalfa

Culturing leaf protoplast-derived cells of the embryogenic alfalfa (Medicago sativa subsp. varia A2) genotype in the presence of low (1 μm) or high (10 μm) 2, 4-dichlorophenoxyacetic acid (2,4-D) concentrations results in different cell types. Cells exposed to high 2,4-D concentration remain small with dense cytoplasm and can develop into proembryogenic cell clusters, whereas protoplasts cultured at low auxin concentration elongate and subsequently die or form undifferentiated cell colonies. Fe stress applied at nonlethal concentrations (1 mm) in the presence of 1 μm2,4-D also resulted in the development of the embryogenic cell type. Although cytoplasmic alkalinization was detected during cell activation of both types, embryogenic cells could be characterized by earlier cell division, a more alkalic vacuolar pH, and nonfunctional chloroplasts as compared with the elongated, nonembryogenic cells. Buffering of the 10 μm 2,4-D-containing culture medium by 10 mm2-(N-morpholino)ethanesulfonic acid delayed cell division and resulted in nonembryogenic cell-type formation. The level of endogenous indoleacetic acid (IAA) increased transiently in all protoplast cultures during the first 4 to 5 d, but an earlier peak of IAA accumulation correlated with the earlier activation of the division cycle in embryogenic-type cells. However, this IAA peak could also be delayed by buffering of the medium pH by 2-(N-morpholino)ethanesulfonic acid. Based on the above data, we propose the involvement of stress responses, endogenous auxin synthesis, and the establishment of cellular pH gradients in the formation of the embryogenic cell type.

Cell cycle phase specificity of putative cyclin-dependent kinase variants in synchronized alfalfa cells.

The eukaryotic cell division cycle is coordinated by cyclin-dependent kinases (CDKs), represented by a single major serine/threonine kinase in yeasts (Cdc2/CDC28) and a family of kinases (CDK1 to CDK8) in human cells. Previously, two cdc2 homologs, cdc2MsA and cdc2MsB, have been identified in alfalfa (Medicago sativa). By isolating cDNAs using a cdc2MsA probe, we demonstrate here that at least four additional cdc2 homologous genes are expressed in the tetraploid alfalfa. Proteins encoded by the new cdc2MsC to cdc2MsF cDNAs share the characteristic functional domains of CDKs with the conserved and plant-specific sequence elements. Transcripts from cdc2MsA, cdc2MsB, cdc2MsC, and cdc2MsE genes are synthesized throughout the cell cycle, whereas the amounts of cdc2MsD and cdc2MsF mRNAs peak during G2-to-M phases. The translation of Cdc2MsA/B, Cdc2MsD, and Cdc2MsF proteins follows the pattern of transcript accumulation. The multiplicity of kinase complexes with cell cycle phase-dependent activities was revealed by in vitro phosphorylation experiments. Proteins bound to p13suc1-Sepharose or immunoprecipitated with Cdc2MsA/B antibodies from cells at G1-to-S and G2-to-M phase boundaries showed elevated kinase activities. the Cdc2MsF antibodies separated a G2-to-M phase-related kinase complex. Detection of histone H1 phosphorylation activities in fractions immunoprecipitated with antimitotic cyclin (CyclinMs2) antibodies from G2-to-M phase cells indicates the complex formation between this cyclin and a kinase partner in alfalfa. The observed fluctuation of transcript levels, amounts, and activities of kinases in different cell cycle phases reflects a multilevel regulatory system during cell cycle progression in plants.

Somatic embryogenesis — Stress-induced remodeling of plant cell fate

Plants as sessile organisms have remarkable developmental plasticity ensuring heir continuous adaptation to the environment. An extreme example is somatic embryogenesis, the initiation of autonomous embryo development in somatic cells in response to exogenous and/or endogenous signals. In this review I briefly overview the various pathways that can lead to embryo development in plants in addition to the fertilization of the egg cell and highlight the importance of the interaction of stress- and hormone-regulated pathways during the induction of somatic embryogenesis. Somatic embryogenesis can be initiated in planta or in vitro, directly or indirectly, and the requirement for dedifferentiation as well as the way to achieve developmental totipotency in the various systems is discussed in light of our present knowledge. The initiation of all forms of the stress/hormone-induced in vitro as well as the genetically provoked in planta somatic embryogenesis requires extensive and coordinated genetic reprogramming that has to take place at the chromatin level, as the embryogenic program is under strong epigenetic repression in vegetative plant cells. Our present knowledge on chromatin-based mechanisms potentially involved in the somatic-to-embryogenic developmental transition is summarized emphasizing the potential role of the chromatin to integrate stress, hormonal, and developmental pathways leading to the activation of the embryogenic program. The role of stress-related chromatin reorganization in the genetic instability of in vitro cultures is also discussed. This article is part of a Special Issue entitled: Stress as a fundamental theme in cell plasticity.

Production of transgenic maize plants by direct DNA uptake into embryogenic protoplasts

Abstract Fertile transgenic maize plants were regenerated after direct transfer of a chimeric gene into maize protoplasts. Plasmid DNA containing mutant dihydrofolate reductase (DHFR) mouse gene, that confers methotrexate (MTX) resistance, under the control of the CaMV 35S promoter was introduced into maize embryogenic protoplasts by polyethylene glycol (PEG) treatment. Transformation was also carried out with a modified plasmid in which the selective marker gene casette was cloned into the BstBI site of the Ds 1 maize transposable element. Resistant callus tissues grown in the presence of 10 −6 or 10 −7 M MTX were selected and shoot or plant regeneration was achieved under hormone-free culture conditions. The presence of the introduced DHFR gene in DNA isolated from the selected colonies and the primary regenerants (T 0 ) was shown by Southern hybridization and PCR analysis. PCR primers for the 35S promoter and for two regions of the coding sequence of the DHFR gene were used for amplification of the foreign sequence present in maize genomic DNA. The PCR products were hybridized with a mouse DHFR gene specific probe. Synthesis of the mouse DHFR in MTX resistant maize tissues was detected by staining for enzyme activity after native PAGE. The in vitro regenerated plants could be grown up to maturity in the greenhouse. Cross pollination has resulted in seeds and the F 1 progenies were also analyzed. In addition to the segregation of MTX-resistant and-sensitive offsprings, molecular evidences based on Southern data and PCR analysis have indicated that the introduced gene was transferred in the first sexual generation. This report provides a new example for potentials in the use of embryogenic cereal protoplasts for production of fertile transgenic crop plants.

Phytoglobins can interfere with nitric oxide functions during plant growth and pathogenic responses: a transgenic approach

To investigate the possible role of the non-symbiotic plant hemoglobins (phytoglobins) in relation to nitric oxide (NO) functions and their presumable involvement in NO- or pathogenesis-induced necrosis, we have produced transgenic tobacco plants (HOT lines) overexpressing an alfalfa hemoglobin cDNA (Mhb1 ) under the control of CaMV35S promoter. Upon treatment with active sodium nitroprusside (SNP), a widely used NO donor, the germination of seeds and development of seedlings were significantly less retarded in transgenic lines compared with the retardation of non-transformed seedlings. SNP-injection necrotized mature plant leaves of Mhb1 -transformants to a lower extent than control leaves. Furthermore, infection of tobacco leaves either with Pseudomonas syringae pv. phaseolicola or Tobacco Necrosis Virus (TNV) resulted in reduced necrosis of mature transgenic plants. In response to bacterial infection, reactive oxygen species (ROS) and salicylic acid (SA) were produced at a higher level in transgenic HOT plants than in control ones. The presented experimental data support a conclusion that plant non-symbiotic hemoglobins are active functional partners in NO-dependent physiological responses such as alteration of plant growth and development as well as cell death and symptom generation after pathogen infection. The described experiments provide new insights to the role of phytoglobins in ROS-, NO- and SA-mediated cellular events during the induction of necrotic cell death. # 2003 Elsevier Ireland Ltd. All rights reserved.

The involvement of reactive oxygen species (ROS) in the cell cycle activation (G0-to-G1 transition) of plant cells

Reactive oxygen species (ROS) are involved in various cellular processes in plants. Among those, resistance to abiotic stress, defence mechanisms and cell expansion have been intensively studied during the last years. We recently demonstrated that ROS, in concert with auxin, have a role in cell cycle activation of differentiated leaf cells.1 In this addendum we provide further evidence to show that oxidative stress/ROS accelerate auxin-mediated cell cycle entry (G0-to-G1 Addendum to: Pasternak TP, Ötvös K, Domoki M, Fehér A. Linked activation of cell division and oxidative stress defense in alfalfa leaf protoplast-derived cells is dependent on exogenous auxin. Plant Growth Regul 2007; 51:109-17.

Exogenous auxin and cytokinin dependent activation of CDKs and cell division in leaf protoplast-derived cells of alfalfa

Alfalfa leaf protoplast cultures were used to study the role ofexogenously supplied auxin and cytokinin on the level and activity ofCdc2-related protein kinases and progression through the first celldivision cycle after re-activation of cell division. Among the threealfalfa Cdc2-related kinases studied, the Cdc2MsA/B kinase (PSTAIRE)showed only significant activity during the first four days ofprotoplast culture while the Cdc2MsD (PPTALRE) and Cdc2MsF kinases(PPTTLRE) exhibited only low or undetectable activity, respectively,during this period. Although the Cdc2MsA/B protein could be detectedin leaves and freshly isolated protoplasts in variable amounts, thekinase was never active in these cells. The kinase protein disappearedfrom protoplast-derived cells at the beginning (8h) of culture but itssynthesis re-commenced dependent on the presence of exogenous auxin butnot cytokinin. The cytokinin response of alfalfa protoplast-derivedcells varied significantly in different experiments although cytokininwas always required for completion of the first cell division cycle.Frequently both auxin and cytokinin was required for DNA replication asnot more than 5% of cells could incorporate BrdU into their DNAduring three days and significant Cdc2MsA/B activity could not bedetected in the absence of exogenous cytokinin. In other protoplastpopulations, the Cdc2MsA/B kinase was activated by auxin alone andallowed the protoplast-derived cells to enther the S-phase at a similarrate observed in parallel cultures with both auxin and cytokinin. Evenin these cultures, however, ca. 95% of the protoplast-derivedcells were arrested before mitosis without exogenous cytokinin supplywhich could be correlated with decreasing Cdc2MsA/B activity. Theseobservations suggest, that although cytokinin is required for bothG0-G1/S and G2/M cell cycle transitions, in certain cultures theG1/S requirement is overcome by some unknown factors (e.g.conditions of explants; endogenous cytokinins etc.). Furthermore, ourexperiments indicate, that the roles of cytokinin are related to thepost-translational regulation of the Cdc2MsA/B kinase complex atboth cell cycle transition points in alfalfa leaf protoplast-derivedcells. Finally, as a marker for the transition from the differentiated(G0) stage to the activated (G1) stage, we suggest using the parametersof nuclear morphology (size and ratio ofnucleus/nucleolus).

Isolation of a full-length mitotic cyclin cDNA clone CycIIIMs from Medicago sativa: Chromosomal mapping and expression

Cyclins in association with the protein kinase p34cdc2and related cyclin-dependent protein kinases (cdks) are key regulatory elements in controlling the cell division cycle. Here, we describe the identification and characterization of a full-length cDNA clone of alfalfa mitotic cyclin, termed CycIIIMs. Computer analysis of known plant cyclin gene sequences revealed that this cyclin belongs to the same structural group as the other known partial alfalfa cyclin sequences. Genetic segregation analysis based on DNA-DNA hybridization data showed that the CycIIIMs gene(s) locates in a single chromosomal region on linkage group 5 of the alfalfa genetic map between RFLP markers UO89A and CG13. The assignment of this cyclin to the mitotic cyclin class was based on its cDNA-derived sequence and its differential expression during G2/M cell cycle phase transition of a partially synchronized alfalfa cell culture. Sequence analysis indicated common motifs with both the A- and B-types of mitotic cyclins similarly to the newly described B3-type of animal cyclins.

Characterization of morphological variation and cold resistance in interspecific somatic hybrids between potato (Solanum tuberosum L.) and S. brevidens Phil.

SummarySomatic hybrids between Solanum tuberosum L. cv. Gracia (2n=4x=48) and Solanum brevidens Phil. (2n=2x=24) were produced via fusion of mesophyll protoplasts. Selection of the protoplast derived putative hybrid calli was based on their vigorous growth. Additive isozyme patterns and chromosome numbers as well as the expression of parental morphological characters have proved the hybrid origin of the selected regenerants. Extensive chromosome loss during the regeneration process resulted in aneuploid hybrids with high frequency. Genomic instability could not be detected in these plants during the period of vegetative propagation. Regenerants from hybrid tissues exhibited wide morphological variation especially in tuber formation. The detailed morphological analysis based on the use of multivariate method (principal component analysis, PCA) enabled to identify morphological groups among the hybrid clones. The positioning of hybrid clones in the PCA space could not be correlated with chromosome numbers. The genomic ratio represented by the tetraploid and diploid parents influenced the morphology of somatic hybrid population according to the applied analytical system. Two selected hybrid clones have exhibited an intermediate degree of frost tolerance compared to the parents, based on the recovery of plants from lower buds after freezing of potted plants.