Identification of a Wee1–Like Kinase Gene Essential for Procyclic Trypanosoma brucei Survival

Regulation of eukaryotic cell cycle progression requires sequential activation and inactivation of cyclin-dependent kinases (CDKs). Activation of the cyclin B-cdc2 kinase complex is a pivotal step in mitotic initiation and the tyrosine kinase Wee1 is a key regulator of cell cycle sequence during G2/M transition and inhibits mitotic entry by phosphorylating the inhibitory tyrosine 15 on the cdc2 M-phase-inducing kinase. Wee1 degradation is essential for the exit from the G2 phase. In trypanosomatids, little is known about the genes that regulate cyclin B-cdc2 complexes at the G2/M transition of their cell cycle. Although canonical tyrosine kinases are absent in the genome of trypanosomatids, phosphorylation on protein tyrosine residues has been reported in Trypanosoma brucei. Here, we characterized a Wee1-like protein kinase gene from T. brucei. Expression of TbWee1 in a Schizosaccharomyces pombe strain null for Wee1 inhibited cell division and caused cell elongation. This demonstrates the lengthening of G2, which provided cells with extra time to grow before dividing. The Wee1-like protein kinase was expressed in the procyclic and bloodstream proliferative slender forms of T. brucei and the role of Wee1 in cell cycle progression was analyzed by generating RNA interference cell lines. In the procyclic form of T. brucei, the knock-down of TbWee1 expression by RNAi led to inhibition of parasite growth. Abnormal phenotypes showing an increase in the percentage of cells with 1N0K, 0N1K and 2N1K were observed in these RNAi cell lines. Using parasites with a synchronized cell cycle, we demonstrated that TbWee1 is linked to the G2/M phase. We also showed that TbWee1 is an essential gene necessary for proper cell cycle progression and parasite growth in T. brucei. Our results provide evidence for the existence of a functional Wee1 in T. brucei with a potential role in cell division at G2/M.     

The D-type cyclin gene (Nicta;CycD3;4) controls cell cycle progression in response to sugar availability in tobacco

D-type cyclins play key roles in the G1-to-S phase transition that occurs in response to nutrient and hormonal signals. In higher plants, sucrose is the major transported carbon source, and is likely to be a major determinant of cell division. To elucidate how sugar affects on the regulation of cell cycle machinery and plant development, we examined the role of carbon sources on the expression of cell-cycle-related genes in transgenic tobacco plants overexpressing Nicta;CycD3;4. The Nicta;CycD3;4 overexpressed transgenic plants showed accelerated growth and remarkable increase in the number of cells in the S and G2 phases in response to sucrose concentrations. Increased expressions level of Nicta;CycD3;4 gene was observed in transgenic tobacco plants grown on 1/2 strength MS medium supplemented with a high concentration of sugar. Moreover, the expression of sugar-sensing-related gene, invertase, was also maintained at a high level in transgenic tobacco plants with elevated sugar availabiliy. These findings indicate that sugar availability plays a role during the G1 phase and the transition of the G1-to-S phase of cell cycle by controlling the expression of Nicta;CycD3;4.     

The Protein Kinase Cdr2, Related to Nim1/Cdr1 Mitotic Inducer, Regulates the Onset of Mitosis in Fission Yeast

Cdc2–Cyclin B, the protein kinase that catalyzes the onset of mitosis, is subject to multiple forms of regulation. In the fission yeast Schizosaccharomyces pombe and most other species, a key mode of Cdc2–Cyclin B regulation is the inhibitory phosphorylation of Cdc2 on tyrosine-15. This phosphorylation is catalyzed by the protein kinases Wee1 and Mik1 and removed by the phosphatase Cdc25. These proteins are also regulated, a notable example being the inhibition of Wee1 by the protein kinase Nim1/Cdr1. The temperature-sensitive mutation cdc25–22 is synthetic lethal with nim1/cdr1 mutations, suggesting that a synthetic lethal genetic screen could be used to identify novel mitotic regulators. Here we describe that such a screen has identified cdr2⁺, a gene that has an important role in the mitotic control. Cdr2 is a 775 amino acid protein kinase that is closely related to Nim1 and mitotic control proteins in budding yeast. Deletion of cdr2 causes a G2-M delay that is more severe than that caused by nim1/cdr1 mutations. Genetic studies are consistent with a model in which Cdr2 negatively regulates Wee1. This model is supported by experiments showing that Cdr2 associates with the N-terminal regulatory domain of Wee1 in cell lysates and phosphorylates Wee1 in vitro. Thus, Cdr2 is a novel mitotic control protein that appears to regulate Wee1.     

The Accumulation of Glycine Betaine Is Dependent on Choline Monooxygenase (OsCMO), Not on Phosphoethanolamine N-Methyltransferase (OsPEAMT1), in Rice (Oryza sativa L. ssp. japonica)

Glycine betaine (GB) is an important osmoprotectant, which improves plant tolerance to various abiotic stresses. In higher plants, GB is synthesized through two-step oxidations of choline, catalyzed by choline monooxygenase (CMO) and betaine aldehyde dehydrogenase (BADH), respectively. Choline, the precursor of GB, is synthesized by phosphoethanolamine N-methyltransferase (PEAMT). Rice is known as a typical non-GB-accumulated species. However, the underlying mechanism related to GB accumulation remains elusive. Here, we determined whether the endogenous accumulation of choline is sufficient to GB biosynthesis in rice and whether the rice CMO protein has the function of oxidizing choline to generate betaine aldehyde. The results showed that overexpression of the rice PEAMT1 gene (OsPEAMT1) resulted in increased levels of choline, while GB content remained unchanged in the transgenic rice plants overexpressing OsPEAMT1. However, the intracellular GB level and the tolerance to salt stress of the transgenic lines overexpressing OsCMO were significantly enhanced. Immunoblotting analysis demonstrated that abundant functional OsCMO proteins with correct size were detected in OsCMO-overexpressing transgenic rice plants, but rarely accumulated in the wild type. Collectively, these results implicated that the endogenous accumulation level of choline is not the major factor leading to non-GB accumulation in rice. Instead, the defective expression of OsCMO resulted in non-GB accumulation.     

An S-locus receptor-like kinase plays a role as a negative regulator in plant defense responses

Plant cells often use cell surface receptors to sense environmental changes and then transduce external signals via activated signaling pathways to trigger adaptive responses. In Arabidopsis, the receptor-like protein kinase (RLK) gene family contains more than 600 members, and some of these are induced by pathogen infection, suggesting a possible role in plant defense responses. We previously characterized an S-locus RLK (CBRLK1) at the biochemical level. In this study, we examined the physiological function of CBRLK1 in defense responses. CBRLK1 mutant and CBRLK1-overexpressing transgenic plants showed enhanced and reduced resistance against a virulent bacterial pathogen, respectively. The altered pathogen resistances of the mutant and overexpressing transgenic plants were associated with increased and reduced induction of the pathogenesis-related gene PR1, respectively. These results suggest that CBRLK1 plays a negative role in the disease resistance signaling pathway in Arabidopsis.     

Overexpression of RoDELLA impacts the height, branching, and flowering behaviour of Pelargonium?×?domesticum transgenic plants

Key message

We reported the cloning of a rose DELLA gene. We obtained transgenic Pelargonium lines overexpressing this gene which presented several phenotypes in plant growth, root growth, flowering time and number of inflorescences.

Abstract

Control of development is an important issue for production of ornamental plant. The plant growth regulator, gibberellins (GAs), plays a pivotal role in regulating plant growth and development. DELLA proteins are nuclear negative regulator of GA signalling. Our objective was to study the role of GA in the plant architecture and in the blooming of ornamentals. We cloned a rose DELLA homologous gene, RoDELLA, and studied its function by genetic transformation of pelargonium. Several transgenic pelargonium (Pelargonium?×?domesticum ‘Autum Haze’) lines were produced that ectopically expressed RoDELLA under the control of the 35S promoter. These transgenic plants exhibited a range of phenotypes which could be related to the reduction in GA response. Most of transgenic plants showed reduced growth associated to an increase of the node and branch number. Moreover, overexpression of RoDELLA blocked or delayed flowering in transgenic pelargonium and exhibited defects in the root formation. We demonstrated that pelargonium could be used to validate ornamental gene as the rose DELLA gene. RoDELLA overexpression modified many aspects of plant developmental pathways, as the plant growth, the transition of vegetative to floral stage and the ability of rooting.     

The effect of ICK1, a plant cyclin-dependent kinase inhibitor,on mitosis in living plant cells

The inhibitory activity of Arabidopsis thaliana ICK1, a plant cyclin-dependent kinase inhibitor, has previously been characterised by its effect on plant cyclin-dependent kinase activity in vitro and its effect on growth in transgenic plants. Herein, we examine cyclin-dependent kinase-driven cell-cycle events, probed by testing the sensitivity of living cells to introduced ICK1 protein. The microinjection of ICK1 into individual Tradescantia virginiana stamen hair cells during late prophase and prometaphase resulted in a clear protein-specific increase in the metaphase transit time (time from nuclear envelope breakdown to the onset of anaphase) in a manner dependent on load and injection time. The results indicate a continuing role for cyclin-dependent kinases in mitotic progression and provide in vivo evidence at the cellular level that ICK1 can restrict growth in the plant by inhibiting cell division.     

Homologous expression of γ-glutamylcysteine synthetase increases grain yield and tolerance of transgenic rice plants to environmental stresses

Various environmental stresses induce reactive oxygen species (ROS), causing deleterious effects on plant cells. Glutathione (GSH), a critical antioxidant, is used to combat ROS. GSH is produced by γ-glutamylcysteine synthetase (γ-ECS) and glutathione synthetase (GS). To evaluate the functional roles of the Oryza sativa L. Japonica cv. Ilmi ECS (OsECS) gene, we generated transgenic rice plants overexpressing OsECS under the control of an inducible promoter (Rab21). When grown under saline conditions (100 mM) for 4 weeks, 2-independent transgenic (TGR1 and TGR2) rice plants remained bright green in comparison to control wild-type (WT) rice plants. TGR1 and TGR2 rice plants also showed a higher GSH/GSSG ratio than did WT rice plants in the presence of 100 mM NaCl, which led to enhanced redox homeostasis. TGR1 and TGR2 rice plants also showed lower ion leakage and higher chlorophyll-fluorescence when exposed to 10 μM methyl viologen (MV). Furthermore, the TGR1 and TGR2 rice seeds had approximately 1.5-fold higher germination rates in the presence of 200 mM salt. Under paddy field conditions, OsECS-overexpression in transgenic rice plants increased rice grain yield (TGW) and improved biomass. Overall, our results show that OsECS overexpression in transgenic rice increases tolerance and germination rate in the presence of abiotic stress by improving redox homeostasis via an enhanced GSH pool. Our findings suggest that increases in grain yield by OsECS overexpression could improve crop yields under natural environmental conditions.     

Activation Domain-dependent Degradation of Somatic Wee1 Kinase

Cell cycle progression is dependent upon coordinate regulation of kinase and proteolytic pathways. Inhibitors of cell cycle transitions are degraded to allow progression into the subsequent cell cycle phase. For example, the tyrosine kinase and Cdk1 inhibitor Wee1 is degraded during G₂ and mitosis to allow mitotic progression. Previous studies suggested that the N terminus of Wee1 directs Wee1 destruction. Using a chemical mutagenesis strategy, we report that multiple regions of Wee1 control its destruction. Most notably, we find that the activation domain of the Wee1 kinase is also required for its degradation. Mutations in this domain inhibit Wee1 degradation in somatic cell extracts and in cells without affecting the overall Wee1 structure or kinase activity. More broadly, these findings suggest that kinase activation domains may be previously unappreciated sites of recognition by the ubiquitin proteasome pathway.     

Overexpression of AtNHX5 improves tolerance to both salt and water stress in rice (Oryza sativa L.)

Overexpression of NHX genes has been previously shown to improve salt tolerance of transgenic plants. In this study, transgenic rice plants overexpressing AtNHX5 showed not only high salt tolerance, but also high drought tolerance. Measurements of ion levels indicated that Na⁺ and K⁺ contents were all higher in AtNHX5 overexpressing shoots than in wild type (WT) shoots in high saline conditions. After exposure to water deficiency and salt stress, the WT plants all died, while the AtNHX5 overexpressing rice plants had a higher survival rate, dry weight, leaf water content, and leaf chlorophyll contents, accumulated more proline, and had less membrane damage than the WT plants. In addition, seeds of both transgenic and WT plants germinated on 1/2 MS medium supplemented with 250 mM mannitol, but overexpression of AtNHX5 improved the shoot growth of the seedlings. Taken together, the results indicate that AtNHX5 gene could enhance the tolerance of rice plants to multiple environmental stresses by promoting the accumulation of more effective osmolytes (ions or proline) to counter the osmotic stress caused by abiotic factors.     

Expression of a plant defensin in rice confers resistance to fungal phytopathogens

Transgenic rice (Oryza sativa L. cv. Pusa basmati 1), overexpressing the Rs-AFP2 defensin gene from the Raphanus sativus was generated by Agrobacterium tumefaciens-mediated transformation. Expression levels of Rs-AFP2 ranged from 0.45 to 0.53% of total soluble protein in transgenic plants. It was observed that constitutive expression of Rs-AFP2 suppresses the growth of Magnaporthe oryzae and Rhizoctonia solani by 77 and 45%, respectively. No effect on plant morphology was observed in the Rs-AFP2 expressing rice lines. The inhibitory activity of protein extracts prepared from leaves of Rs-AFP2 plants on the in vitro growth of M. oryzae indicated that the Rs-AFP2 protein produced by transgenic rice plants was biologically active. Transgene expression of Rs-AFP2 was not accompanied by an induction of pathogenesis-related (PR) gene expression, suggesting that the expression of Rs-AFP2 directly inhibits the pathogens. Here, we demonstrate that transgenic rice plants expressing the Rs-AFP2 gene show enhanced resistance to M. oryzae and R. solani, two of the most important pathogens of rice.     

Overexpression of <Emphasis Type="Italic">TaNHX2</Emphasis> enhances salt tolerance of ‘composite’ and whole transgenic soybean plants

Salinity is a major factor resulting in extensive loss of agricultural production. Genetic transformation has become a powerful tool for studying gene function and for improving crop salt tolerance. In this study, a TaNHX2 gene was transformed into a plant cloning vector under the control of cauliflower mosaic virus 35S promoter, and then introduced into Agrobacterium rhizogenes strain K599. Explants of soybean were transformed with A. rhizogenes and ‘composite’ plants consisting of wild-type shoots and transgenic hairy roots overexpressing TaNHX2 were produced. When exposed to salt stress, ‘composite’ plants displayed high salinity tolerance at 171 mM NaCl in vermiculite and in solid medium supplemented with up to 200 mM NaCl, whereas control plants displayed chlorosis and died within 15 days under above treatment conditions. We subsequently obtained soybean plants overexpressing TaNHX2 through A. tumefaciens-mediated transformation and studied four homozygous lines of TaNHX2. Transgenic lines displayed an enhanced salt tolerance in plant biomass and flower number per plant, compared with wild type plants grown on sand culture containing 150 mM NaCl. Furthermore, transgenic plants of line C12-11 showed longer survival, less growth inhibition and greater number of flowers than wild type plants. Taken together, these results indicated that TaNHX2 gene could enhance salt tolerance of soybean, and A. rhizogenes-mediated transformation system could be used as a complementary tool of A. tumerfaciens-mediated transformation to rapidly investigate candidate gene function in soybean.     

Functional role of rice germin-like protein1 in regulation of plant height and disease resistance

The functional role of rice (Oryza sativa) germin-like protein1 (OsGLP1) was elucidated through development of transgenic plants involving endogenous gene silencing in rice and heterologous gene expression in tobacco. Usually, the single copy OsGLP1 gene in rice plant was found to be expressed predominantly in green vegetative tissues. The transgenic rice lines showed significant reduction in endogenous OsGLP1 expression due to 26 nt siRNA-mediated gene silencing, displayed semi-dwarfism and were affected seriously by fungal diseases, compared to the untransformed plant. Structural homology modeling predicted a superoxide dismutase (SOD) domain in OsGLP1 protein which upon over-expression in transgenic tobacco plant clearly documented SOD activity. Our observations on the maintenance of cell dimension, cell wall-associated localization particularly in the sub-epidermal tissues and the SOD activity of OsGLP1 could explain its functional role in regulation of plant height and disease resistance in rice plant.     

Enhanced production of reducing sugars from transgenic rice expressing exo-glucanase under the control of a senescence-inducible promoter

We generated transgenic rice plants that express EXG1 exo-glucanase under the control of a senescence-inducible promoter. When a GUS coding sequence was connected to a promoter region of STAY GREEN (SGR) gene of rice and introduced into rice, GUS activity was specifically observed along with senescence. When an EXG1 cDNA was connected to the SGR promoter and introduced into rice, higher cellulase activities were detected after senescence. The EXG1 transgenic plants showed enhanced enzymatic saccharification efficiencies after senescence, but no significant difference of saccharification efficiencies was observed before senescence. The saccharification efficiencies were correlated with the cellulase activities in the transgenic plants. The EXG1 transgenic plants showed neither morphological abnormality nor sterility, both of which were observed when EXG1 was constitutively overexpressed. These results indicate that expression of cell wall degrading enzymes such as cellulase by a senescence-inducible promoter is one of the ways to enhance the saccharification ability of cellulosic biomass without affecting plant growth for efficient production of biofuels.     

Fission Yeast Nod1 Is a Component of Cortical Nodes Involved in Cell Size Control and Division Site Placement

Most cells enter mitosis once they have reached a defined size. In the fission yeast Schizosaccharomyces pombe, mitotic entry is orchestrated by a geometry-sensing mechanism that involves the Cdk1/Cdc2-inhibiting Wee1 kinase. The factors upstream of Wee1 gather together in interphase to form a characteristic medial and cortical belt of nodes. Nodes are also considered to be precursors of the cytokinesis contractile actomyosin ring (CAR). Here we describe a new component of the interphase nodes and cytokinesis rings, which we named Nod1. Consistent with its role in cell size control at division, nod1Δ cells were elongated and epistatic with regulators of Wee1. Through biochemical and localisation studies, we placed Nod1 in a complex with the Rho-guanine nucleotide exchange factor Gef2. Nod1 and Gef2 mutually recruited each other in nodes and Nod1 also assembles Gef2 in rings. Like gef2Δ, nod1Δ cells showed a mild displacement of their division plane and this phenotype was severely exacerbated when the parallel Polo kinase pathway was also compromised. We conclude that Nod1 specifies the division site by localising Gef2 to the mitotic cell middle. Previous work showed that Gef2 in turn anchors factors that control the spatio-temporal recruitment of the actin nucleation machinery. It is believed that the actin filaments originated from the nodes pull nodes together into a single contractile ring. Surprisingly however, we found that node proteins could form pre-ring helical filaments in a cdc12-112 mutant in which nucleation of the actin ring is impaired. Furthermore, the deletion of either nod1 or gef2 created an un-expected situation where different ring components were recruited sequentially rather than simultaneously. At later stages of cytokinesis, these various rings appeared inter-fitted rather than merged. This study brings a new slant to the understanding of CAR assembly and function.