[Abnormal floral meristem development in transgenic tomato plants do not depend on the expression of genes encoding defense-related PR-proteins and antimicrobial peptides].

In this study, the morphological and cytoembryological analyses of the tomato plants transformed with the genes encoding chitin-binding proteins (ac and RS-intron-Shir) from Amaranthus caudatus L. andA. retroflexus L., respectively, as well as the gene amp2 encoding hevein-like antimicrobial peptides from Stellaria media L., have been performed. The transgenic lines were adapted to soil and grown the greenhouse. The analysis of putative transgenic tomato plants revealed several lines that did not differ phenotypically from the wild type plants and three lines with disruption in differentiation of the inflorescence shoot and the flower, as well as the fruit formation (modified plants of each line were transformed with a single gene as noted before). Abnormalities in the development of the generative organs were maintained for at least six vegetative generations. These transgenic plants were shown to be defective in the mail gametophyte formation, fertilization, and, consequently, led to parthenocarpic fruits. The detailed analysis of growing ovules in the abnormal transgenic plants showed that the replacement tissue was formed and proliferated instead of unfertilized embryo sac. The structure of the replacement tissue differed from both embryonic and endosperm tissue of the normal ovule. The formation of the replacement tissue occurred due to continuing proliferation of the endothelial cells that lost their ability for differentiation. The final step in the development of the replacement tissue was its death, which resulted in the cell lysis. The expression of the genes used was confirmed by RT-PCR in all three lines with abnormal phenotype, as well as in several lines that did not phenotypically differ from the untransformed control. This suggests that abnormalities in the organs of the generative sphere in the transgenic plants do not depend on the expression of the foreign genes that were introduced in the tomato genome. Here, we argue that agrobacterial transformation affects, directly or indirectly, expression of genes encoding for transcription factors that can activate a gene cascade responsible for the normal plant development.

[Antipodal complex development in the embryo sac of wheat].

Dynamics of an antipodal complex formation in wheat (Triticum aestivum L.) has been observed in detail using a reconstruction of serial semifine sections. Three consecutive crucial stages have been identified in the development of the antipodal complex: (1) proliferation of initial cells, (2) growth and functional differentiation of antipodal cells, and (3) cell apoptosis. Specific features of the mitotic division of antipodal cells have been characterized. It has been shown that the structure of interphase nuclei and mitotic chromosomes of proliferating antipodal cells is similar to that of nucellar cells surrounding the embryo sac. According to the reconstruction of appropriately oriented serial sections, the division of antipodal cells is asynchronous. DNA content in differentiated antipodal cells has been determined by a cytophotometric analysis; in the case of a mature embryo sac, the ploidy of antipodal cells varied from 8 to 32C. Proliferation and DNA endoreduplication processes in the antipodal complex proceed at different time; the second process starts only after the termination of the first one. DNA endoreduplication is accompanied by total chromatin remodeling; as a result, giant chromosomes are formed in the nuclei of antipodal cells. The final stage of the antipodal complex development is programmed cell death or apoptosis. A model for the structural organization of an antipodal complex has been proposed based on the layer arrangement of cells. The secretory activity of antipodal cells directed towards the endosperm syncytium has been detected for the first time. The analysis of "truncated" ovules with an undeveloped endosperm has shown that developing endosperm can be a possible inductor, which stimulates the functional activity of antipodal cells and triggers their terminal differentiation. The obtained results evidence the functional role of antipodal cells in the development of the endosperm and embryo.

[Phase transitions in lyotropic liquid crystals: bilayer and micelle stability]. / Fazovye perekhody v liotropnykh zhidkikh kristallakh: stabil'nost' bisloev i mitsell.

A model for describing hydrophile and hydrophobic interactions was introduced. On the basis of this model a phase diagram was calculated for transitions of homogeneous mixture amphyphyl--water into pure, intermediate and isotropic phases. Coefficients of the model introduced were found from the comparison with the experimental data. A relative role of electrostatic interaction was evaluated and compared with hydrophile and hydrophobic ones.