Fruit and seed anatomy of Chenopodium and related genera (Chenopodioideae, Chenopodiaceae/Amaranthaceae): implications for evolution and taxonomy.

A comparative carpological study of 96 species of all clades formerly considered as the tribe Chenopodieae has been conducted for the first time. The results show important differences in the anatomical structure of the pericarp and seed coat between representatives of terminal clades including Chenopodium s.str.+Chenopodiastrum and the recently recognized genera Blitum, Oxybasis and Dysphania. Within Chenopodium the most significant changes in fruit and seed structure are found in members of C. sect. Skottsbergia. The genera Rhagodia and Einadia differ insignificantly from Chenopodium. The evolution of heterospermy in Chenopodium is discussed. Almost all representatives of the tribe Dysphanieae are clearly separated from other Chenopodioideae on the basis of a diverse set of characteristics, including the small dimensions of the fruits (especially in Australian taxa), their subglobose shape (excl. Teloxys and Suckleya), and peculiarities of the pericarp indumentum. The set of fruit and seed characters evolved within the subfamily Chenopodioideae is described. A recent phylogenetic hypothesis is employed to examine the evolution of three (out of a total of 21) characters, namely seed color, testa-cell protoplast characteristics and embryo orientation.

[The ultrastructural characteristics of Neisseria meningitidis strains isolated in different forms of infection]. / Osobennosti ul'trastruktury shtammov Neisseria meningitidis, vydelennykh pri razlichnykh formakh infektsii.

The electron microscopic study of cell populations of the first generation of several N.meningitidis strains, isolated from humans and grown on artificial culture medium (Hottinger's serum agar) has made it possible to establish that these organisms are morphologically heterogeneous. It was manifested by the presence of 7 morphological variants of cells in their cultures (different strains have different proportions of these variants): (a) "normal" and similar to normal diplococcal variants; (b) atypically dividing cells; (c) spheroplastic forms; (d) protoplastic forms (typical and atypical); (e) variably gemmating forms; (f) microforms and (g) gigantic forms. These data are of interest for the microbiological diagnosis of meningitis.

Flow cytometric characterization of the chlorophyll contents and size distributions of plant protoplasts.

We have employed flow cytometry for the characterization of populations of protoplasts prepared from tobacco (Nicotiana tabacum) leaf tissues. We first investigated the possibility of using flow cytometric analysis of the emission of chlorophyll autofluorescence for measurement of the chlorophyll contents of leaf protoplasts. Defined numbers of leaf protoplasts were sorted according to different, nonoverlapping windows placed on the one-dimensional histograms of chlorophyll autofluorescence emission. The amounts of cellular chlorophyll were measured in cell-free extracts of these sorted protoplasts using fluorometry. A high degree of correlation (r2 = 0.983) was observed between these two parameters. We then examined the distribution of protoplast diameters in these protoplast populations through the use of pulse-width time-of-flight (TOF) analysis. Through sorting of protoplasts using a series of narrow, nonoverlapping TOF windows, we were able to demonstrate that the TOF parameter was linearly correlated with protoplast diameter, over the range of 15-55 micron (r2 greater than 0.99). We also compared the use of fluorescein diacetate (FDA) fluorochromasia and chlorophyll autofluorescence as the source of fluorescent signals for TOF analysis. We found that the presence of chloroplasts introduced distortions into the measurement of apparent size afforded by TOF analysis of FDA fluorochromasia. These results are discussed in terms of the application of techniques of flow analysis and sorting for the measurement of gene expression within the various different cell types found in plant tissues and organs.