Patterns of actin filaments during cell shaping in developing mesophyll of wheat (Triticum aestivum L.).

Young leaves of wheat exhibit a smooth developmental gradient with meristematic cells at the base and highly differentiated cells at the tip. During differentiation, mesophyll cells attain a lobed outline resembling tube-shaped balloons with almost regularly spaced isthmi. Microfilament patterns in developing wheat mesophyll cells were investigated using fluorescent-labeled phalloidin. Various patterns were found, including delicate arrays of transversely oriented microfilaments in the cortex of the cytoplasm. A close correlation between changes in the patterns of cortical microfilaments, microtubules, cell wall microfibrils, and cell shape was observed. The fine arrays of transversely oriented microfilaments coaligned with bands of microtubules occurring during cell elongation. These bands were found beneath sites of intense wall deposition. It has recently been proposed that the resulting hoops of wall reinforcement prevent cell expansion in the corresponding regions and thus give rise to the peculiar cell shape. When cell expansion ceased, and the typical lobed cell shape was attained, a dense network of microfilaments was retained in the cytoplasm, which was in contrast to what has been described for the microtubular arrays.     

Role of cytoskeleton in cell shaping of developing mesophyll of wheat (Triticum aestivum L.).

The effects of oryzalin and cytochalasin B (CB) on microtubule and actin microfilament arrays and on cell shaping were investigated in developing wheat mesophyll. Excised immature leaf sections capable of differentiating were incubated with the drugs. The behavior of the cytoskeleton was monitored by fluorescence microscopy after labeling with fluorescent dyes. Brief incubation with oryzalin (40 min, 10 microM) caused disassembly of microtubules. Recovery of microtubule arrays was comparatively slow after removal of the drug. Cells failed to establish transverse cortical bands of microtubules and transverse hoops of wall reinforcement. They expanded isodiametrically rather than longitudinally without forming lobes typical of wheat mesophyll cells. Brief treatment with CB (60 min, 20 micrograms ml-1) appeared to disrupt the microfilament arrays. Filaments recovered rapidly after removal of CB, and cells were able to shape in an apparently normal fashion. Continuous incubation at comparatively low concentration of CB (4 micrograms ml-1) appeared to cause selective loss of the fine transverse cortical microfilament arrays. Cortical transverse microtubule arrays persisted, but failed to form distinct bands in the majority of the cells. Cells were able to elongate in an almost normal fashion, but no lobes were formed.     

Faspad: fast signaling pathway detection

Faspad is a user-friendly tool that detects candidates for linear signaling pathways in protein interaction networks based on an approach by Scott et al. (Journal of Computational Biology, 2006). Using recent algorithmic insights, it can solve the underlying NP-hard problem quite fast: for protein networks of typical size (several thousand nodes), pathway candidates of length up to 13 proteins can be found within seconds and with a 99.9% probability of optimality. Faspad graphically displays all candidates that are found; for evaluation and comparison purposes, an overlay of several candidates and the surrounding network context can also be shown. Availability: Faspad is available as free software under the GPL license at http://theinf1.informatik.uni-jena.de/faspad/ and runs under Linux and Windows.     

FANMOD: a tool for fast network motif detection

SUMMARY: Motifs are small connected subnetworks that a network displays in significantly higher frequencies than would be expected for a random network. They have recently gathered much attention as a concept to uncover structural design principles of complex biological networks. FANMOD is a tool for fast network motif detection; it relies on recently developed algorithms to improve the efficiency of network motif detection by some orders of magnitude over existing tools. This facilitates the detection of larger motifs in bigger networks than previously possible. Additional benefits of FANMOD are the ability to analyze colored networks, a graphical user interface and the ability to export results to a variety of machine- and human-readable file formats including comma-separated values and HTML.     

β-NEUROTOXIN REDUCES NEUROTRANSMITTER STORAGE IN BRAIN SYNAPSES

β-neurotoxin, a component of Bungarus multicinctus venom, is known to cause neuromuscular blockade by first increasing the rate of spontaneous ACh release and then inhibiting the nerve impulse-induced release of ACh. We report that the toxin also affects the storage of several neurotransmitters in rat brain and it is active on synaptosomes and brain minces. Synaptosomes prepared from brain tissue that had been treated with β-toxin have a reduced ability to accumulate radioactive NE, GABA, serotonin and the ACh precursor, choline. The toxin also causes a release of previously accumulated NE and GABA from synaptosomes, suggesting that the storage process rather than the uptake transport process is affected. The toxin does not contain phospholipase A, phospholipase C, protease or hyaluronidase activity.     

The ambiguous role of 2,4-dichlorophenoxyacetic acid in wheat tissue culture

The very basal, highly immature regions of dissected young leaves of Triticum aestivum L. cv. Kite formed adventitious roots on a nutrient medium supplemented with comparatively low concentrations (0.16 to 0.63 μ M ) of 2,4-dichlorophenoxyacetic acid (2,4-D). Higher concentrations (up to 640 μ M ) had to be applied to stimulate growth from more mature regions higher up the leaf. Yet, already at 2.5 μ M roots were less distinct and more callus-like, and eventually (at 10 to 640 μ M ) only a subculturable callus of apparently suppressed, slowly proliferating root primordia developed. Furthermore, at the most basal, highly immature regions growth was significantly retarded when the auxin concentration was raised. The leaf culture system appears to reflect the dual action of 2,4-D known from herbicide research, namely growth stimulation from differentiating (or differentiated) cells, but growth suppression at or in the vicinity of apical meristems. Correspondingly, when the callus of apparently suppressed, slowly proliferating root primordia was transferred to media without 2,4-D or with low concentrations (0.16–2.5 μ M ) rapid proliferation commenced, leading to profuse root outgrowth. The system demonstrates the ambiguous role which this auxin appears to have, at least in wheat tissue culture.     

Embryogenesis from cultured immature inflorescences ofSorghum bicolor

Summary A method for reproducibly initiating tissue cultures from immature sorghum inflorescences is described. The cultures are maintained through the proliferation of embryo-like structures and shoot primordia, which under appropriate conditions grow further to form plants. Evidence is presented that these structures develop from a tissue similar to that found in the scutellum of immature embryos, which arises from superficial cells of the inflorescence expiants. Possible applications of such a system are discussed.Abbreviations 2,4-D 2,4-Dichlorophenoxyacetic acid - MS Murashige and Skoog - 6-BAP 6-Benzylaminopurine - EDTA Ethylenediaminetetraacetic acid - Kinetin 6-Fur-furylaminopurine     

THE MECHANISM OF ACTION OF β-BUNGAROTOXIN

—β-Bungarotoxin, a presynaptically-acting polypeptide neurotoxin, caused an efflux from synaptosomes of previously accumulated γ-aminobutyric acid and 2-deoxy-d -glucose. The toxin-induced efflux of γ-aminobutyric acid occurred by a Na⁺ -dependent process while that of 2-deoxyglucose was Na⁺ -independent. These effects were also produced by treating synaptosomes with low molecular weight compounds, including fatty acids, that inhibit oxidative phosphorylation. After incubation with β-bungarotoxin, synaptosomes exhibited increased production of ¹⁴CO₂ from [U-¹⁴C]glucose and decreased ATP levels. β-Bungarotoxin treatment of various subcellular membrane fractions caused the production of a factor that uncoupled oxidative phosphorylation when added to mitochondria. Mitochondria from toxin-treated brain tissue exhibited a limitation in the maximal rate of substrate utilization. We conclude that β-bungarotoxin acts by inhibiting oxidative phosphorylation in the mitochondria of nerve terminals. This inhibition accounts for the observed β-bungarotoxin effects on synaptosomes and at neuromuscular junctions. We suggest that the effects on energy metabolism result from a phospholipase A activity found to be associated with the toxin.