Claudia Jonak

Cell numbers and leaf development in Arabidopsis: a functional analysis of the STRUWWELPETER gene

The struwwelpeter (swp) mutant in Arabidopsis shows reduced cell numbers in all aerial organs. In certain cases, this defect is partially compensated by an increase in final cell size. Although the mutation does not affect cell cycle duration in the young primordia, it does influence the window of cell proliferation, as cell number is reduced during the very early stages of primordium initiation and a precocious arrest of cell proliferation occurs. In addition, the mutation also perturbs the shoot apical meristem (SAM), which becomes gradually disorganized. SWP encodes a protein with similarities to subunits of the Mediator complex, required for RNA polymerase II recruitment at target promoters in response to specific activators. To gain further insight into its function, we overexpressed the gene under the control of a constitutive promoter. This interfered again with the moment of cell cycle arrest in the young leaf. Our results suggest that the levels of SWP, besides their role in pattern formation at the meristem, play an important role in defining the duration of cell proliferation.

A MAP Kinase Is Activated Late in Plant Mitosis and Becomes Localized to the Plane of Cell Division

In eukaryotes, mitogen-activated protein kinases (MAPKs) are part of signaling modules that transmit diverse stimuli, such as mitogens, developmental cues, or various stresses. Here, we report a novel alfalfa MAPK, Medicago MAP kinase 3 (MMK3). Using an MMK3-specific antibody, we detected the MMK3 protein and its associated activity only in dividing cells. The MMK3 protein could be found during all stages of the cell cycle, but its protein kinase activity was transient in mitosis and correlated with the timing of phragmoplast formation. Depolymerization of microtubules by short treatments with the drug amiprophosmethyl during anaphase and telophase abolished MMK3 activity, indicating that intact microtubules are required for MMK3 activation. During anaphase, MMK3 was found to be concentrated in between the segregating chromosomes; later, it localized at the midplane of cell division in the phragmoplast. As the phragmoplast microtubules were redistributed from the center to the periphery during telophase, MMK3 still localized to the whole plane of division; thus, phragmoplast microtubules are not required to keep MMK3 at this location. Together, these data strongly support a role for MMK3 in the regulation of plant cytokinesis.

Differential activation of four specific MAPK pathways by distinct elicitors

Plant cells respond to elicitors by inducing a variety of defense responses. Some of these reactions are dependent on the activity of protein kinases. Recently, mitogen-activated protein kinases (MAPKs) have been identified to be activated by fungal and bacterial elicitors as well as by pathogen infection. In gel kinase assays of alfalfa cells treated with yeast cell wall-derived elicitor (YE) revealed that 44- and 46-kDa MAPKs are rapidly and transiently activated. Immunokinase assays with specific MAPK antibodies revealed that YE mainly activated the 46-kDa SIMK and the 44-kDa MMK3 and to a lesser extent the 44-kDa MMK2 and SAMK. When cells were treated with chemically defined elicitors potentially contained in the YE (chitin and N-acetylglucosamine oligomers, β-glucan, and ergosterol), the four MAPKs were found to be activated to different levels and with different kinetics. Whereas SIMK and SAMK have been found to be activated by a number of diverse stimuli, MMK3 is activated during mitosis and was therefore assumed to participate in cell division (22). No physiological process could be associated with MMK2 activity so far. This is the first report that MMK2 and MMK3 can be activated by external stimuli. Overall, our findings indicate that plant cells can sense different cues of a given microorganism through the activation of multiple MAPKs.

Alfalfa cyclins: differential expression during the cell cycle and in plant organs.

Cell division in eukaryotes is mediated by the action of the mitosis promoting factor, which is composed of the CDC2 protein kinase and one of the various mitotic cyclins. We have recently isolated a cdc2 gene from alfalfa. Here, we report the isolation of two cyclin genes, cycMs1 and cycMs2, from alfalfa. The cycMs2 gene shows highest similarity to type B cyclins. In contrast, the predicted amino acid sequence of the cycMs1 gene shows similar homology scores to cyclins of all types (25 to 35%). Both genes are expressed in dividing suspension cultured cells but cease to be expressed when the cells enter stationary phase. In synchronized alfalfa suspension cultured cells, the mRNAs of cycMs1 and cycMs2 show maximal expression in the G2 and M phases. Transcripts of cycMs2 are found only in late G2 and M phase cells, an expression pattern typical for cyclin B genes, whereas cycMs1 appears with the onset of G2. This pattern indicates that alfalfa cycMs1 and cycMs2 belong to different classes of cyclins. In young leaves, expression of both genes is high, whereas in mature leaves no transcripts can be detected, indicating that the two cyclin genes are true cell division markers at the mRNA level. In other organs, a more complex expression pattern of the two cyclin genes was found.

Glycogen synthase kinase 3/SHAGGY-like kinases in plants: an emerging family with novel functions

Animal glycogen synthase kinase 3 (GSK-3)/SHAGGY kinases have been studied for more than 20 years, whereas plant glycogen synthase kinase 3/SHAGGY-like kinases (GSKs) have only recently entered the scene. Present evidence indicates that plant GSKs are involved in different processes, such as flower development, brassinosteroid signaling, NaCl stress and wound responses. In contrast to mammals, which contain two genes, plants have a multigene family of GSKs. Analysis of the Arabidopsis genome revealed the existence of ten GSK genes that fall into four distinct subfamilies. We discuss the functions and mechanisms of GSK action in plants and other organisms.

MAP kinases: universal multi-purpose signaling tools

MAP (mitogen-activated protein) kinases are serine/threonine protein kinases and mediate intracellular phosphorylation events linking various extracellular signals to different cellular targets. MAP kinase, MAP kinase kinase and MAP kinase kinase kinase are functional protein kinase units that are conserved in several signal transduction pathways in animals and yeasts. Isolation of all three components was also shown in plants and suggests conservation of a protein kinase module in all eukaryotic cells. In plants, MAP kinase modules appear to be involved in ethylene signaling and auxin-induced cell proliferation. Therefore, coupling of different extracellular signals to different physiological responses is mediated by MAP kinase cascades and appears to have evolved from a single prototypical protein kinase module which has been adapted to the specific requirements of different organisms.

Wound-Induced Expression and Activation of WIG, a Novel Glycogen Synthase Kinase 3

Glycogen synthase kinase 3 (GSK-3) is involved in the regulation of several physiological processes, including glycogen metabolism, protein synthesis, transcription factor activity, and developmental control. Although GSK-3–like genes have been isolated from plants, no function for any of these kinases has been defined. We report here that the alfalfa wound-induced gene (WIG, for wound-induced GSK-3), lencoding a functional plant GSK-3–like kinase, is activated when the alfalfa leaves are wounded. Although WIG transcripts are hardly detectable in mature leaves, WIG mRNA accumulates rapidly after wounding. Using a peptide antibody that specifically recognizes p53WIG, we show that p53WIG kinase is activated immediately after wounding. Wound-induced activation of p53WIG kinase is a post-translational process, because the concentrations of p53WIG protein do not change in intact and wounded leaves, and inhibition of transcription or translation does not block activation by wounding. However, inactivation of p53WIG kinase, which usually occurs within 60 min after wounding, is dependent on transcription and translation of one or more protein factors. These data suggest that the WIG kinase is involved in wound signaling in plants.

Inflorescence-specific expression of AtK-1, a novel Arabidopsis thaliana homologue of shaggy~glycogen synthase kinase-3

We report here the isolation of the Arabidopsis thaliana gene AtK-1. The predicted protein sequence of AtK-1 show 70% identity to the Arabidopsis ASK and alfalfa MsK kinases that are homologs of the Drosophila shaggy and rat GSK-3 serine/threonine protein kinases playing an important role in signal transduction processes in animals. Northern analysis of different organs revealed exclusive expression in inflorescences suggesting an involvement of the AtK-1 kinase in reproduction-specific processes.

Cells and domains: Two views of the shoot meristem in Arabidopsis

All aerial parts of a plant are generated by groups of dividing cells called shoot meristems. These structures determine the arrangement and number of the different organs they produce, and, as a consequence the architecture of the plant largely depends on meristem activity. Extensive morphological studies have led to a model which postulates that shoot meristems are organised into functionally and morphologically distinct zones. According to this model, the centre of the meristem is responsible for cell production and meristem maintenance, whereas the periphery will initiate the organ primordia. Recently, genetic analysis allowed the identification of mutants affected in different functions of the meristem and some of the genes involved have now been identified. Meristem function also depends on the strict coordination of morphogenesis at the cellular level, as illustrated by the highly ordered patterns of cell division, division plane alignment and cell expansion observed in many species. Over the past few years, our understanding of the molecular mechanisms that control cell proliferation and growth has progressed significantly. Therefore, we can now start to unravel the networks that link these basic cellular processes to the regulators that control plant development at the level of the whole meristem.

MAP Kinases in Plant Signal Transduction: VersatileTools for Signaling Stress, Cell Cycle, and More

Mitogen-activated protein kinase (MAPK) pathways are modules involved in the transduction of extracellular signals to intracellular targets in all eukaryotes. Distinct MAPK pathways are regulated by different extracellular stimuli and are implicated in a wide variety of biological processes. In plants, there exists a large number of highly conserved MAPK genes. The presently available evidence indicates that some of these MAPKs play a role in the signal transduction of abiotic stress, pathogens, plant hormones, and cell cycle cues.