Release of developmental constraints on tetrad shape is confirmed in inaperturate pollen of Potamogeton

Background and Aims

Microsporogenesis in monocots is often characterized by successive cytokinesis with centrifugal cell plate formation. Pollen grains in monocots are predominantly monosulcate, but variation occurs, including the lack of apertures. The aperture pattern can be determined by microsporogenesis features such as the tetrad shape and the last sites of callose deposition among the microspores. Potamogeton belongs to the early divergent Potamogetonaceae and possesses inaperturate pollen, a type of pollen for which it has been suggested that there is a release of the constraint on tetrad shape. This study aimed to investigate the microsporogenesis and the ultrastructure of pollen wall in species of Potamogeton in order to better understand the relationship between microsporogenesis features and the inaperturate condition.

Methods

The microsporogenesis was investigated using both light and epifluorescence microscopy. The ultrastructure of the pollen grain was studied using transmission electron microscopy.

Key Results

The cytokinesis is successive and formation of the intersporal callose wall is achieved by centrifugal cell plates, as a one-step process. The microspore tetrads were tetragonal, decussate, T-shaped and linear, except in P. pusillus, which showed less variation. This species also showed a callose ring in the microsporocyte, and some rhomboidal tetrads. In the mature pollen, the thickening observed in a broad area of the intine was here interpreted as an artefact.

Conclusions

The data support the view that there is a correlation between the inaperturate pollen production and the release of constraint on tetrad shape. However, in P. pusillus the tetrad shape may be constrained by a callose ring. It is also suggested that the lack of apertures in the pollen of Potamogeton may be due to the lack of specific sites on which callose deposition is completed. Moreover, inaperturate pollen of Potamogeton would be better classified as omniaperturate.Key words: Alismatales, callose, microsporogenesis, pollen aperture, Potamogeton illinoensis, P. polygonus, P. pusillus, tetrad shape     

High-throughput screening assay of hepatitis C virus helicase inhibitors using fluorescence-quenching phenomenon

We have developed a novel high-throughput screening assay of hepatitis C virus (HCV) nonstructural protein 3 (NS3) helicase inhibitors using the fluorescence-quenching phenomenon via photoinduced electron transfer between fluorescent dyes and guanine bases. We prepared double-stranded DNA (dsDNA) with a 5′-fluorescent-dye (BODIPY FL)-labeled strand hybridized with a complementary strand, the 3′-end of which has guanine bases. When dsDNA is unwound by helicase, the dye emits fluorescence owing to its release from the guanine bases. Our results demonstrate that this assay is suitable for quantitative assay of HCV NS3 helicase activity and useful for high-throughput screening for inhibitors. Furthermore, we applied this assay to the screening for NS3 helicase inhibitors from cell extracts of microorganisms, and found several cell extracts containing potential inhibitors.     

Alkaloids inhibiting l-histidine decarboxylase from Sinomenium acutum

Chromatographic separation of an extract of the stems of Sinomenium acutum resulted in the isolation of two new alkaloids, 2-O-demethyl-acutumine (4), and 6-O-methyl-laudanosoline-1-O-glucoside (5), together with three known alkaloids, sinomenine (1), sinomenine N-oxide (2), and magnoflorine (3). Sinomenine was found to show good inhibitory activity toward l-histidine decarboxylase from Lactobacillus 30a with an IC₅₀ value of 969 μM but its N-oxide showed no inhibition of this enzyme. Sinomenine inhibited this enzyme in a noncompetitive manner with a K_i of 762 μM.     

A novel and simple micro-irradiation technique for creating localized DNA double-strand breaks

An ataxia-telangiectasia mutated (ATM)-dependent DNA damage signal is amplified through the interaction of various factors, which are recruited to the chromatin regions with DNA double-strand breaks. Spatial and temporal regulation of such factors is analysed by fluorescence microscopy in combination with laser micro-irradiation. Here we describe a novel and simple technique for micro-irradiation that does not require a laser source. Cells were labelled with BrdU for 48–72 h, covered with porous polycarbonate membranes, and exposed to UVC. All BrdU-labelled cells showed localized foci of phosphorylated ATM, phosphorylated histone H2AX, MDC1 and 53BP1 upon irradiation, showing that these foci were induced irrespective of the cell-cycle phase. They were also detectable in nucleotide excision repair-defective XPA cells labelled with BrdU, indicating that the foci did not reflect an excision repair-related process. Furthermore, an ATM-specific inhibitor significantly attenuated the foci formation, and disappearance of the foci was significantly abrogated in non-homologous end-joining-defective cells. Thus, it can be concluded that micro-irradiation generated DNA double-strand breaks in BrdU-sensitized cells. The present technique should accelerate research in the fields of DNA damage response, DNA repair and DNA recombination, as it provides more chances to perform micro-irradiation experiments without any specific equipment.     

Cellulase production on glucose-based media by the UV-irradiated mutants of Trichoderma reesei

From 22,791 mutants of a cellulase hyper-producing strain of Trichoderma reesei (Hypocrea jecorina), ATCC66589, as the parent, we selected two mutants, M2-1 and M3-1, that produce cellulases in media containing both cellulose and glucose. The mutation enabled the mutants to produce cellulases, which were measured as p-nitrophenyl β-d-lactopyranoside-hydrolyzing activities, in media with glucose as a sole carbon source, although M2-1 exhibited different sensitivities to glucose from M3-1. When the mutants were grown for 8 days on a medium with cellulose as a sole carbon source, the filter-paper-degrading activities (FPAs) per gram of cellulose were 257 and 281 U for M2-1 and M3-1, respectively, values that were 1.1–1.2 times higher than that of the parental strain. Cellulase production by M2-1 and M3-1 on a medium with a continuously fed mixture of glucose and cellobiose resulted in 214 and 210 U of FPA/gram carbon sources, respectively, whereas less efficient production (140 U of FPA/gram carbon source) was achieved by the parental strain. The improved cellulase productivity of the mutants allows us to use glucose as a carbon source for efficient on-site production of cellulases with quality/quantity-controlled feeding of soluble carbon sources and inducers.     

A Novel Fluorescent Sensor Protein for Visualization of Redox States in the Cytoplasm and in Peroxisomes

Reactive oxygen species are generated within peroxisomes during peroxisomal metabolism. However, due to technological difficulties, the intraperoxisomal redox state remain elusive, and the effect of peroxisome deficiency on the intracellular redox state is controversial. A newly developed, genetically encoded fluorescence resonance energy transfer (FRET) probe, Redoxfluor, senses the physiological redox state via its internal disulfide bonds, resulting in a change in the conformation of the protein leading to a FRET response. We made use of Redoxfluor to measure the redox states at the subcellular level in yeast and Chinese hamster ovary (CHO) cells. In wild-type peroxisomes harboring an intact fatty acid β-oxidation system, the redox state within the peroxisomes was more reductive than that in the cytosol, despite the fact that reactive oxygen species were generated within the peroxisomes. Interestingly, we observed that the redox state of the cytosol of cell mutants for peroxisome assembly, regarded as models for a neurological metabolic disorder, was more reductive than that of the wild-type cells in yeast and CHO cells. Furthermore, Redoxfluor was utilized to develop an efficient system for the screening of drugs that moderate the abnormal cytosolic redox state in the mutant CHO cell lines for peroxisome assembly without affecting the redox state of normal cells.Peroxisomes are single membrane-bound organelles harboring at least one H₂O₂-generating oxidase and one H₂O₂-decomposing catalase, and they are present in virtually all eukaryotic cells, from yeast to mammals. The most conserved activity of peroxisomal metabolism is the β-oxidation of fatty acids (27).Peroxisome assembly requires more than 20 PEX gene products, termed peroxins, in any given organism (5). The impairment of peroxisomal protein transport caused by mutations in PEX genes causes fatal human peroxisome biogenesis disorders (PBDs) (34). In the cells of such PBD patients, essential enzymes normally localized to peroxisomes are found mostly in the cytosol. Mammalian cell lines harboring mutations in peroxins (including fibroblasts from PBD patients) grow well in cell culture. On the other hand, pex mutants of the methylotrophic yeast Pichia pastoris can grow normally on glucose but not oleate or methanol (37).Peroxisomal metabolic pathways can generate a high level of reactive oxygen species (ROS) (32). Therefore, peroxisomal disorders have been studied with a focus on the generation of ROS. However, the relationship between PBDs and the intracellular redox state is unclear (13, 32).Peroxisomes have long been thought to be in a more highly oxidized state than the cytosol due to this generation of ROS. However, there is no reported experimental evidence supporting this notion. We previously identified a 20-kDa peroxisomal membrane protein, named Pmp20, in methanol-induced peroxisomes of methylotrophic yeasts. Pmp20 had a glutathione (GSH) peroxidase activity, suggesting the presence of glutathione within the peroxisomes (9). However, we and other groups of investigators have been unable to determine the levels of the reduced and oxidized forms of glutathione due to technical difficulties and therefore have been unable to assess the redox state within peroxisomes by conventional biochemical methods.In general, the intracellular redox state is determined by the levels of redox-related metabolites that are generated by multiple metabolic pathways. (We herein refer to the “redox state” as an intracellular environment at steady state, which is distinct from oxidative stress or ROS, which functions as a signal for further intracellular events such as apoptosis.) Therefore, the redox state is considered to reflect the overall metabolic status. While the standard redox potential (E₀′) is a general index used to express the redox state of a compound, it cannot be used to describe the intracellular redox state because it does not take into account various physiological considerations, such as the cytosol, where many compounds coexist in a mixture of various redox states (14). Therefore, the equilibrium redox state in living cells has been estimated from indices such as the ratio of oxidized and reduced forms of glutathione, from indirect indices of the redox state, such as the NAD(P)H ratio (12, 40), or from the level of the expression of antioxidant enzymes. However, the measurement of these indices often yields contradictory results, making it difficult to evaluate the physiological redox state using any single index. This situation might have led to misunderstanding the redox state in cells from patients with PBDs. Reductive conditions could occur during conditions of oxidative stress, when the ROS defense system is functioning normally.With the aim of determining the intracellular redox state directly, we developed a fluorescent redox probe, Redoxfluor, with a novel sensing mechanism. Several green fluorescent protein (GFP) variants that report the in vivo redox state (roGFP [4, 7], rxYFP [18, 24, 25]) or H₂O₂ level (HyPer [3]) have been developed since the start of our research. However, none of these reporters have been used to visualize the redox state in mammalian cytosol, and differences in the redox potential between normal and pathological states have not been reported.In the present work, we developed a Redoxfluor that discriminates the redox state of peroxisome assembly mutant cell lines (34) from that of the normal cell line. Our findings shed light on how to tackle problems with monitoring the spatiotemporal dynamics of the redox state within living mammalian cells and also should pave the way for the development of a screen for drugs that can affect various metabolic disorders with abnormal redox state.     

VanB-vanA incongruent VRE isolated from animals and humans in 1999

16 chicken isolates and four clinical isolates of VanB-vanA incongruent vancomycinresistant Enterococcus faecium strains without vanS were isolated in 1999. Pulsed-field gel electrophoresis revealed only a peripheral relationship between the chicken isolates and clinical isolates, but suggested clonal spread in the chicken isolates.     

Adrenomedullin insufficiency increases allergen-induced airway hyperresponsiveness in mice.

Adrenomedullin (ADM), a newly identified vasodilating peptide, is reported to be expressed in lungs and have a bronchodilating effect. We hypothesized whether ADM could be involved in the pathogenesis of bronchial asthma. We examined the role of ADM in airway responsiveness using heterozygous ADM-deficient mice (AM+/-) and their littermate control (AM+/+). Here, we show that airway responsiveness is enhanced in ADM mutant mice after sensitization and challenge with ovalbumin (OVA). The immunoreactive ADM level in the lung tissue after methacholine challenge was significantly greater in the wild-type mice than that in the mutant. However, the impairment of ADM gene function did not affect immunoglobulins (OVA-specific IgE and IgG1), T helper 1 and 2 cytokines, and leukotrenes. Thus the conventional mechanism of allergen-induced airway responsiveness is not relevant to this model. Furthermore, morphometric analysis revealed that eosinophilia and airway hypersecretion were similarly found in both the OVA-treated ADM mutant mice and the OVA-treated wild-type mice. On the other hand, the area of the airway smooth muscle layer of the OVA-treated mutant mice was significantly greater than that of the OVA-treated wild-type mice. These results suggest that ADM gene disruption may be associated with airway smooth muscle hyperplasia as well as enhanced airway hyperresponsiveness. ADM mutant mice might provide novel insights to study the pathophysiological role of ADM in vivo.     

Biodegradation of a polyvinyl alcohol-starch blend plastic film

Attempts were made to elucidate the degradation mechanism of a polyvinyl alcohol (PVA)-starch blend plastic. A part of the starch fraction of this plastic was dissolved into an aqueous phase in a control test. Treatment with a PVA-degrading bacterium or enzyme gave a maximal weight loss of approximately 70% and film breakage occurred. Since this plastic contains 40% PVA, it is apparent that not only the PVA fraction but also a considerable portion of the starch fraction was lost from the film by treatment with the PVA-degrading enzyme. As the PVA-degrading bacterium and enzyme used here showed no starch-degrading activity, loss of the starch fraction seems to depend on its dissolution with degradation of the PVA fraction. These experimental results indicated that the degradation of the PVA fraction is an important requisite for complete degradation or decomposition of this plastic film.