A synthetic derivative of plant allylpolyalkoxybenzenes induces selective loss of motile cilia in sea urchin embryos.

Polyalkoxybenzenes are plant components displaying a wide range of biological activities. In these studies, we synthesized apiol and dillapiol isoxazoline analogues of combretastatins and evaluated their effect on sea urchin embryos. We have shown that p-methoxyphenyl isoxazoline caused sea urchin embryo immobilization due to the selective excision of motile cilia, whereas long immotile sensory cilia of apical tuft remained intact. This effect was completely reversed by washing the embryos. The compound did not alter cell division, blastulae hatching, and larval morphogenesis. In our hands, the molecule would serve as a convenient tool for in vivo studying morphogenetic processes in the sea urchin embryo. We anticipate that both the assay and the described derivative could be used for studies in ciliary function in embryogenesis.     

Nod factors induce nod factor cleaving enzymes in pea roots. Genetic and pharmacological approaches indicate different activation mechanisms

Establishment of symbiosis between legumes and rhizobia requires bacterial Nod factors (NFs). The concentration of these lipochitooligosaccharides in the rhizosphere is influenced by plant enzymes. NFs induce on pea (Pisum sativum) a particular extracellular NF hydrolase that releases lipodisaccharides from NFs from Sinorhizobium meliloti. Here, we investigated the ability of non-nodulating pea mutants to respond to NodRlv factors (NFs from Rhizobium leguminosarum bv viciae) with enhanced NF hydrolase activity. Mutants defective in the symbiotic genes sym10, sym8, sym19, and sym9/sym30 did not exhibit any stimulation of the NF hydrolase, indicating that the enzyme is induced via an NF signal transduction pathway that includes calcium spiking (transient increases in intracellular Ca(2+) levels). Interestingly, the NF hydrolase activity in these sym mutants was even lower than in wild-type peas, which were not pretreated with NodRlv factors. Activation of the NF hydrolase in wild-type plants was a specific response to NodRlv factors. The induction of the NF hydrolase was blocked by alpha-amanitin, cycloheximide, tunicamycin, EGTA, U73122, and calyculin A. Inhibitory effects, albeit weaker, were also found for brefeldin A, BHQ and ethephon. In addition to this NF hydrolase, NFs and stress-related signals (ethylene and salicylic acid) stimulated a pea chitinase that released lipotrisaccharides from pentameric NFs from S. meliloti. NodRlv factors failed to stimulate the chitinase in mutants defective in the sym10 and sym8 genes, whereas other mutants (e.g. mutated in the sym19 gene) retained their ability to increase the chitinase activity. These findings indicate that calcium spiking is not implicated in stimulation of the chitinase. We suggest that downstream of Sym8, a stress-related signal transduction pathway branches off from the NF signal transduction pathway.     

Adaptive mutagenesis accelerates microorganism evolution only while competing for resources: mathematic modeling

Mathematical simulation of adaptive mutagenesis was carried out. The results obtained indicate that adaptive mutagenesis can play an essential role in the survival of microbial populations. We show that the competition for natural resources is a necessary factor of adaptive mutagenesis.     

Effect of mutations in the pea genes <Emphasis Type="Italic">Sym33</Emphasis> and <Emphasis Type="Italic">Sym40</Emphasis>

Two symbiotic pea (Pisum sativum L.) mutants SGEFix(-)-1 (sym40) and SGEFix(-)-2 (sym33) with abnormalities in infection thread formation in symbiotic root nodules were characterised with respect to dynamics of arbuscule development at 15 degrees C and 24 degrees C. Mutation of sym33 decreased mycorrhiza colonisation at both temperatures and delayed arbuscule development at 15 degrees C, whereas mutation of sym40 accelerated mycorrhiza colonisation and arbuscule senescence at 24 degrees C. The differences between the mutants and the wild-type were more pronounced at 24 degrees C, a temperature close to the optimum for pea growth. The results demonstrate that both pea genes are important in the control of arbuscular mycorrhiza development and can be considered necessary for the tripartite symbiosis in pea.     

Biosynthesis of levorin and activity of several enzyme systems of Streptomyces levoris depending on culture conditions

The regularities of changes in the main oxidation-reduction enzymes of the tricarboxylic acid cycle (TAC) and the pentose cycle were studied under different cultivation conditions: with the use of the control soybean-corn-hydrol medium and the medium with addition of a biostimulant produced by C. tropicalis. It was shown that the activity levels of the dehydrogenase systems of the TAC and the pentose cycle of S. levoris grown in the presence of the biostimulant were higher. The increase in the production levels of levorin due to addition of the biostimulant was connected with the activity of the systems responsible for regeneration of NADP.H2.