Regulation of summer dormancy by water deficit and ABA in Poa bulbosa ecotypes

BACKGROUND AND AIMS: Survival of many herbaceous species in Mediterranean habitats during the dry, hot summer depends on the induction of summer dormancy by changes in environmental conditions during the transition between the winter (growth) season to the summer (resting) season, i.e. longer days, increasing temperature and drought. In Poa bulbosa, a perennial geophytic grass, summer dormancy is induced by long days, and the induction is enhanced by high temperature. Here the induction of summer dormancy in a Mediterranean perennial grass by water deficit under non-inductive photoperiodic conditions is reported for the first time. METHODS: Plants grown under 22/16 degrees C and non-inductive short-day (9 h, SD) were subjected to water deficit (WD), applied as cycles of reduced irrigation, or sprayed with ABA solutions. They were compared with plants in which dormancy was induced by transfer from SD to inductive long-day (16 h, LD). Responses of two contrasting ecotypes, from arid and mesic habitats were compared. Dormancy relaxation in bulbs from these ecotypes and treatments was studied by comparing sprouting capacity in a wet substrate at 10 degrees C of freshly harvested bulbs to that of dry-stored bulbs at 40 degrees C. Endogenous ABA in the bulbs was determined by monoclonal immunoassay analysis. KEY RESULTS: Dormancy was induced by WD and by ABA application in plants growing under non-inductive SD. Dormancy induction by WD was associated with increased levels of ABA. Bulbs were initially deeply dormant and their sprouting capacity was very low, as in plants in which dormancy was induced by LD. Dormancy was released after 2 months dry storage at 40 degrees C in all treatments. ABA levels were not affected by dormancy relaxation. CONCLUSIONS: Summer dormancy in P. bulbosa can be induced by two alternative and probably additive pathways: (1) photoperiodic induction by long-days, and (2) water deficit. Increased levels of endogenous ABA are involved in both pathways.     

Tyrosine phosphorylation of measles virus nucleocapsid protein in persistently infected neuroblastoma cells.

Subacute sclerosing panencephalitis is a slowly progressing fatal human disease of the central nervous system which is a delayed sequel of measles virus (MV) infection. A typical pathological feature of this disease is the presence of viral ribonucleocapsid structures in the form of inclusion bodies and the absence of infectious virus or budding viral particles. The mechanisms governing the establishment and maintenance of a persistent MV infection in brain cells are still largely unknown. To understand the mechanisms underlying MV persistence in neuronal cells, a tissue culture model was studied. Clone NS20Y/MS of the murine neuroblastoma C1300 persistently infected with the wild-type Edmonston strain of MV secretes relatively high levels of alpha/beta interferon (IFN). As shown previously, treatment of the persistently infected cultures with anti-IFN serum converted the persistent state into a productive infection indicated by the appearance of multinucleated giant cells. In this study, we have investigated whether alpha/beta IFN produced by NS20Y/MS cells activates cellular protein tyrosine kinases which will induce tyrosine phosphorylating activity specific to virus-infected cells. We present data to show augmented protein tyrosine kinase activity in the persistently infected cells. We demonstrate that the MV N protein is phosphorylated on tyrosine in addition to serine and threonine in the persistent state but not in NS20Y cells acutely infected with MV.     

Plant growth hormones suppress the development of Harpophora maydis,the cause of late wilt in maize

Late wilt, a severe vascular disease of maize caused by the fungus Harpophora maydis, is characterized by rapid wilting of maize plants before tasseling and until shortly before maturity. The pathogen is currently controlled by resistant maize cultivars, but the disease is constantly spreading to new areas. The plant’s late phenological stage at which the disease appears suggests that plant hormones may be involved in the pathogenesis. This work revealed that plant growth hormones, auxin (Indole-3-acetic acid) and cytokinin (kinetin), suppress H. maydis in culture media and in a detached root assay. Kinetin, and even more auxin, caused significant suppression of fungus spore germination. Gibberellic acid did not alter colony growth rate but had a signal suppressive effect on the pathogens’ spore germination. In comparison, ethylene and jasmonic acid, plant senescing and defense response regulators, had minor effects on colony growth and spore germination rate. Their associate hormone, salicylic acid, had a moderate suppressive effect on spore germination and colony growth rate, and a strong influence when combined with auxin. Despite the anti-fungal auxin success in vitro, field experiments with dimethylamine salt of  2,4-dichlorophenoxyacetic acid (that mimics the influence of auxin) failed to suppress the late wilt. The lines of evidence presented here reveal the suppressive influence of the three growth hormones studied on fungal development and are important to encourage further and more in-depth examinations of this intriguing hormonal complex regulatory and its role in the maize-H. maydis interactions.     

Significance of lytic enzymes from Trichoderma spp. in the biocontrol of fungal plant pathogens

The use of specific mycolytic soil microorganisms to control plant pathogens is an ecological approach to overcome the problems caused by standard chemical methods of plant protection. The ability to produce lytic enzymes is a widely distributed property of rhizosphere-competent fungi and bacteria. Due to the higher activity of Trichoderma spp. lytic enzymes as compared to the same class of enzymes from other microorganisms and plants, effort is being aimed at improving biocontrol agents and plants by introducing Trichoderma genes via genetic manipulations. An overview is presented of the data currently available on lytic enzymes from the mycoparasitic fungus Trichoderma. This revised version was published online in August 2006 with corrections to the Cover Date.     

Silicification patterns in wheat leaves related to ontogeny and soil silicon availability under field conditions

Plant and Soil - Silicon (Si) accumulation is an important strategy for plant defense against biotic and abiotic stress. Solid amorphous silica (ASi) deposits have been found to protect plants...     

Deciphering the principles of the RNA editing code via large-scale systematic probing

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Candida albicans Cyclin Clb4 Carries S-Phase Cyclin Activity

Cyclin-dependent kinases (CDKs) are key regulators of eukaryotic cell cycle progression. The cyclin subunit activates the CDK and also imparts to the complex, at least in some cases, substrate specificity. Saccharomyces cerevisiae, an organism in which the roles of individual cyclins are best studied, contains nine cyclins (three G₁ cyclins and six B-type cyclins) capable of activating the main cell cycle CDK, Cdc28. Analysis of the genome of the pathogenic yeast Candida albicans revealed only two sequences corresponding to B-type cyclins, C. albicans Clb2 (CaClb2) and CaClb4. Notably, no homolog of the S. cerevisiae S-phase-specific cyclins, Clb5/Clb6, could be detected. Here, we performed an in vitro analysis of the activity of CaClb2 and CaClb4 and of three G₁ cyclins, as well as an analysis of the phenotype of S. cerevisiae cells expressing CaClb2 or CaClb4 instead of Clb5. Remarkably, replacement of CLB5 by CaCLB4 caused rapid diploidization of S. cerevisiae. In addition, both in vivo and in vitro analyses indicate that, in spite of the higher sequence similarity of CaClb2 to Clb5/Clb6, CaClb4 is the functional homolog of Clb5/Clb6. The activity of a CaClb2/CaClb4 cyclin hybrid suggests that the cyclin box domain of CaClb4 carries the functional specificity of the protein. These results have implications for our understanding of the evolution of specificity of the cell cycle cyclins.Cyclin-dependent kinases (CDKs) regulate many cellular processes but are best known for their role in the promotion of cell cycle progression. CDK activity depends on the binding of activatory subunits, the cyclins, which periodically appear during the cell cycle. Saccharomyces cerevisiae contains a single essential cell cycle CDK, S. cerevisiae Cdc28 (ScCdc28)/Cdk1, which in turn can be activated by nine cyclins: three G₁-type cyclins (Cln1, Cln2, and Cln3) and six B-type cyclins (S. cerevisiae Clb1 [ScCbl1] to ScCbl6) (34). Cln3 together with Cln1 and Cln2 (Cln1/2) induces a large class of cell cycle-regulated genes, including genes involved in S-phase initiation, such as the B-cyclins Clb5 and Clb6 (Clb5/6) (44, 47). Clb3 and Clb4 are expressed from early S phase to anaphase (22) and play a role in spindle orientation (Clb4) (31) and morphogenesis (Clb3 and Clb4) (25, 37), and Clb1 and Clb2 are expressed in G₂ (22) and play a role in entry into anaphase and spindle elongation (18). Genetic analysis suggests that the genes CLB1 to CLB4 have overlapping functions, as deletions of all four is lethal, but a mutant with deletion of all but CLB2 is still viable (18). Deletion of both CLB5 and CLB6 or of CLB5 alone is not lethal but results in a delay in S-phase initiation (41).The diverged yeast Schizosaccharomyces pombe contains one G₁ cyclin and three B-type cyclins. Studies indicating that a single S. pombe B-type cyclin, Cdc13, is sufficient to promote cell cycle progression led to the suggestion that the cyclin''s function is solely to periodically activate the CDK (17, 32). It is now clear, however, that the cyclin subunit imparts specificity to the CDK in at least some cases. Notably, biochemical analysis suggests that the different cellular function of the S. cerevisiae B-type cyclins may be based upon different substrate specificities: comparative analysis by in vitro phosphorylation of CDK substrates by Clb2-Cdk1 versus Clb5-Cdk1 indicates that whereas Clb2-Cdk1 carries a higher kinase activity toward most substrates, Clb5-Cdk1 is differentially much more active on a subclass of CDK substrates, including many S-phase proteins (30). A specific region of the cyclin box domain of Clb5 was identified that is essential for interaction with S-phase-specific substrates such as Orc6 (46) and Cdc6 (1).Candida albicans is a pathogenic yeast in the order Saccharomycetales, distantly related to S. cerevisiae. Given the cumbersome genetics of C. albicans, a diploid organism lacking a traditional sexual cycle, assignment of gene function in C. albicans has often been informed by sequence comparison with S. cerevisiae. However, the complete genome sequence of C. albicans, while including a Cdk1/Cdc28 homolog as well as sequence homologs of the cyclins Cln1/2, Cln3, Clb2, and Clb4—5 predicted Cdk1/Cdc28 cyclins in total—lacks an obvious homolog of Clb5/6. Here, we show by biochemical analysis and functional complementation that the homologous function of ScClb5 is carried by C. albicans Clb4 (CaClb4).     

Abscisic acid involvement in the induction of summer‐dormancy in Poa bulbosa, a grass geophyte

Summer‐dormancy occurs in geophytes that inhabit regions with a Mediterranean climate (mild, rainy winters and hot, dry summers). The environmental control of summer‐dormancy and the involvement of phytohormones in its induction have been little studied. Poa bulbosa L. is a perennial grass geophyte in which summer‐dormancy is induced by long days and by high temperature. Prolonged treatment with ABA (0.1‐1.0 m M ) under non‐inductive 8‐h short days (SD) resulted in cessation of leaf and tiller production and in the development of typical features of dormancy: bulbing at the base of the tillers and leaf senescence. Short‐term applications of ABA had similar effects but dormancy was transient, i.e. after a short while, leaf growth from the formed bulbs was resumed. ABA treatment of plants growing under an inductive 16‐h photoperiod (LD) enhanced the onset of dormancy. Endogenous levels of ABA in leaf blades and at the tiller base (where the bulb develops) increased markedly after the plants were transferred from SD to LD. This increase was greater in the tiller base, and concomitant with bulb maturation. High temperature (27/22 vs 22/17°C) accelerated both bulb development and ABA accumulation in leaf blades.
These results suggest that ABA plays a key role in the photoperiodic induction and development of summer‐dormancy in P. bulbosa .     

From flour to flower: how Polycomb group proteins influence multiple aspects of plant development

Cell identity and differentiation are determined by patterns of regulatory gene expression. Spatially and temporally regulated homeotic gene expression defines segment identities along the anterior-posterior axis of animal embryos. Polycomb group (PcG) proteins form a cellular memory system that maintains the repressed state of homeotic gene expression. Conserved PcG proteins control multiple aspects of Arabidopsis development and maintain homeotic gene repression. In animals, PcG proteins repress their target genes by modifying histone tails through deacetylation and methylation, generating a PcG-specific histone code that recruits other chromatin remodeling proteins to establish a stable, heritable mechanism of epigenetic expression control. Plant PcG proteins might function through a similar biochemical mechanism owing to their conserved structural and functional relationship to animal PcG proteins.