Preparation of mitochondrial DNAs from sunflowers (Helianthus annuus L.) and from beets (Beta vulgaris) using a medium with a high ionic strength

The isolation of mitochondria from sugar beet and sunflower has been carried outina buffered medium of high ionic strength (I=1.40 M). Them tDNAs obtained were enriched for supercoiled molecules of low molecular weight. Chloroplast and mitochondrial DNA were successively prepared and used from a single leaf preparation for further analysis of restriction fragment length polymorphism. The few available wild relatives of sugar beet or sunflower have also been analyzed by comparison of the restriction patterns of their chloroplast and mitochondrial DNAs.     

Transmission of paternal chloroplasts in Nicotiana

Summary Transmission of paternal chloroplasts was observed in Nicotiana, considered to inherit organelles in a strictly maternal way. Plants carrying streptomycin resistant plastids were used as pollen donors. Cell lines with paternal plastids in the offspring were selected as green (resistant) sectors on calli induced from the seedlings on streptomycin-containing media. The presence of paternal plastids in the regenerated plants was confirmed by restriction analysis. In the Nicotiana plumbaginifolia xN. plumbaginifolia Np(SR1)3 and the N. plumbaginifolia Np(gos)29 xN. tabacum SR1 crosses 2.5% and 0.07% of the offspring were found to contain paternal (tabacum) plastids, respectively. These plants, however, carried maternal mitochondria exclusively. This sexual cybridization method offers a simple way to transfer chloroplasts solely, a goal not accessible by protoplast fusion.     

Organellar DNA synthesis in permeabilized soybean cells

Summary Cultured cells of Glycine max (L.) Merr. v. Corsoy were permeabilized by treatment with L--lysophosphatidylcholine (LPC). The permeabilized cells were capable of uptake and incorporation of deoxynucleoside triphosphates into DNA. Incorporation of exogenous nucleotides into DNA was linear for at least 90 minutes and the initial rate of incorporation approached 50% of the theoretical in vivo rate of DNA synthesis. However, DNA synthesis in the permeabilized cells was unaffected by the potent DNA polymerase inhibitor, aphidicolin. Analysis of newly synthesized DNA by molecular hybridization revealed that only organellar DNA was synthesized by the permeabilized cells. The LPC treated cells were also permeable to a protein as large as DNase I. The permeabilized cells were capable of RNA and protein synthesis as indicated by incorporation of radiolabeled UTP and leucine, respectively, into acid-precipitable material.     

Evolution of the cytoplasmic organelles during female meiosis in Pisum sativum L.

In this paper we have traced the evolution of the cytoplasmic organelles in the female germinal cell of Pisum sativum L., from the beginning of meiosis to the early stages of the maturing megaspore, in order to correlate the morphological changes with the physiological aspects of megasporogenesis.A process of intense cytoplasmic vacuolation takes place in the megaspore mother cell (MMC) during prophase I, probably proceeding from the smooth endoplasmic reticulum and dictyosomes; it results in the formation of big vacuoles, which play a role in MMC polarization. By means of this polarization most plastids and mitochondria are incorporated into the functional megaspore at the end of meiosis.There are plastid and mitochondria cycles which consist of dedifferentiation followed by redifferentiation, During these cycles a transient morphology appears, called a cup-shaped form, which we interpret as an expression of low organelle activity.The wall of the MMC thickens throughout megasporogenesis and loses its plasmodesmata during middle prophase I. The ribosome population is reduced during prophase I and then restored during the early stages of the megaspore maturing process, as shown by the quantitative study that we have carried out. The nucleolar cytoplasmic bodies play a part in this restoring process. These bodies have a special morphology and appear to be originated from the activity of the nucleolar organizing region (NOR) during nucleolar disorganization in prophase I.We think that this cytoplasmic evolution is a response to nuclear genic recombination, in order to provide the most adequate expression of the zygote genome.Abbreviations EDTA ethylene-diamine-tetracetic acid - ER endoplasmic reticulum (SER: smooth ER) - MMC megaspore mother cell - NOR nucleolar organizing region - RNP ribonucleoproteins This work has been partially supported by the Comisión Asesora para la investigación Cientifica by Técnica Projects n^o 613/02 and 613/10     

Structure of Monocercomonas sp. as Revealed by Electron Microscopy*

SYNOPSIS. Monocercomonas shares many fine-structural features with all other trichomonads. These include the basic arrangement of the kinetosomes as well as of the recurrent and 3 anterior flagella. The pelta-axostyle complex and the parabasal apparatus, i.e. the Golgi complex and the periodic filaments, also conform to the trichomonad pattern. Of interest with regard to the crucial evolutionary position of Monocercomonas, considered to represent the most primitive trichomonad type, is the fact that it has some structures in common with other Monocercomonadidae and Trichomonadinae and others in common with Devescovinidae and Tritrichomonadinae. Among the former organelles are the marginal lamella and the costal base, and among the latter, the comb-like organelle situated between the infrakinetosomal body and parabasal filament 2 as well as the infrakinetosomal body. No traces of either costa or undulating membrane have been noted, but a complex structure homologous to the marginal lamella of Hypotrichomonas and Trichomonadinae is found underlying the short anteriormost portion of the recurrent flagellum that is attached to the body surface. Observations of sections of selected division stages indicate the potential of parental kinetosomes #1 and #3 to become daughter kinetosome #2.     

The isolation of large quantities of undamaged cellular organelles and cytosolic enzymes using a low-shear continuous tissue homogenizer

There is often a need to isolate large quantities of subcellular components such as membrane-coated organelles (e.g., nuclei, lysosomes, and mitochondria), cell membranes, and soluble (cytosolic) proteins. Instruments which can homogenize relatively large masses of tissue, primarily those with rapidly rotating blades and cylinders, are excessively vigorous, often resulting in damaged and/or low yields of the subcellular components. This paper describes procedures for obtaining high yields of undamaged subcellular components using a continuous bulk tissue homogenizer which performs with low shear (the low-shear continuous homogenizer or LSC). This homogenizer is simple in operation, durable and can be used with a variety of tissues. Fibrous tissues are more difficult to homogenize using this instrumentation and require a premincing to small pieces (0.2 to 1.0-cm diam) followed by filtration through 2-4 mesh (two to four apertures per inch). Methods for bulk preparations with enhanced recoveries of undamaged nuclei, and a typical soluble multimeric enzyme, phosphofructokinase, are presented. Electron microscope views of the homogenates show the preserved state of the other subcellular components. The LSC homogenizer requires less physical effort with no "hands on" operation and thus is safer. This homogenizer requires less homogenization time compared to the smaller, hand-held Potter-Elvehjem-type homogenizers. Operations requiring low temperature can be performed at room temperature as long as the continuously passing homogenate solutions are kept chilled.     

Progress in plant protoplast research

During the past years plant regeneration from protoplasts was achieved for a number of important crops (maize, sorghum, rice, wheat, sugar beet). The use of embryogenic tissue for protoplast isolation greatly contributed to this success. There was also some progress in woody plant species and ornamentals. Fusion of protoplasts resulted in may fertile hybrid plants, especially in the Brassicaceae and Solanaceae. These somatic hybridization studies led to introduction of new agronomical traits from sexually incompatible species into the cultivar gene pool and to new nucleus-organelle compositions. The limitations of somatic hybridization, mainly imposed by the taxonomic distance of the parents, and expressed as chromosome loss and reduced fertility, are more clearly recognized now. Asymmetric hybridization with irradiated donor protoplasts resulted in cybrids with new cytoplasmic traits (e. g. intraspecific fusions in Brassica ), as well as in the transfer of only a few donor choromosomes (e. g. intrageneric fusions in Nicotiana ). Most intrageneric fusions, however, resulted only in a limited elimination of donor chromosomes (e. g. in Lycopersicon ), and polyploidization occurred (e. g. in Nicotiana ). Also some success on protoplast transformation was obtained in both monocots and dicots. Fertile transgenic rice plants (Japonica, Indica) were produced after direct gene transfer into protoplasts derived from embryogenic cell suspensions. Particle gun experiments using embryogenic cell suspension of maize resulted in fertile transgenic plants. Transformation of citrus and lettuce by direct gene transfer was also reported.