Ultrastructural changes in major organelles during spermatial differentiation inBangia (Rhodophyta)

Summary The major organelles within the cells of maleBangia atropurpurea (Roth) C. Ag. filaments undergo a series of ultrastructural transformations during the production of spermatia. Initially, thylakoids within the large axial chloroplast develop a reticulate pattern commencing at the central pyrenoid region. Subsequent changes involve loss of lobes and diminution of volume through division; chloroplasts in final stages contain a few dilated, distorted thylakoids and many plastoglobuli. During differentiation the large nucleolus disappears from the nucleus and four masses of chromatin aggregate near the nuclear envelope. Furrows originating from the nuclear envelope form double membranes around each of the chromatin masses and most of the nucleoplasm is eliminated. Several types of fibrillar vesicles are formed during the process and large floridean starch reserves are utilized. Multilamellar bodies and microbody-like structures occur within the cells during certain phases of spermatiogenesis.     

Hereditary variability of plants under the action of exogenous DNA

Summary Injection of exogenous barley donor DNA into grains of barley recipient plants at the milk maturity stage, with a specially designed syringe, led to the appearance of transformed plants. The transformation (in rare cases) was caused by the unsheared DNA since the DNA passing through the syringe needle remained relatively stable (10⁶ to 10⁷ daltons) as was confirmed by DNA sedimentation analysis.14 plants grown from seeds injected with highly polymeric DNA containing close to 30 per cent protein had transformed pollen grains. In the 2nd generation only 2 plants from the 8 studied preserved these changes. In the progeny of these two plants, i.e., in the 3rd seed generation after injection, 82.1 per cent of plants preserved the transformed characters. The next, 4th generation, preserved a transformed phenotype in 89.6 per cent of plants.It was also shown that reversion to a recipient-like state was not always constant. We found the reversion of transformed properties (i.e., normal starch and two-rowed spikes) in 40 per cent of the 4th generation descendants of one of the plants which had lost the phenotypical expression of these properties in the 3rd generation but had them in the 2nd generation.The study of the morphological properties of transformed plants showed that with respect to phenotypic expression some characters were changed towards the donor type, some remained as in the recipients and some were of the intermediate type.     

Assessment of environmental contamination associated with a mammalian cell transformation assay

Summary To estimate worker exposures to, and environmental contamination from, test chemicals and organic solvents used in an in vitro assay to assess the carcinogenic potential of chemicals, sodium fluorescein, a noncarcinogenic fluorescent material, was dissolved in tissue culture medium used to maintain early passage hamster embryo cells. Personal and environmental samples were taken over a 14-d period. The assay was performed according to standard procedures in a ventilated glove box or laminar flow safety cabinet. Considerably more than 99% of the chemical contamination found was recovered from the interiors of the glove box and hood and from disposable equipment. Contamination outside the containment units (less than 1 μg) resulted from intralaboratory transport of chemicals, treated cultures, and contaminated equipment. We conclude that the standard operating practices and procedures provided adequate safeguards for personnel and the environment. Research sponsored by the National Cancer Institute under Contract N01-CO-75380, with Litton Bionetics, Inc.     

Neutral amino acid transport in surface membrane vesicles isolated from mouse fibroblasts: Intrinsic and extrinsic models of regulation

Membrane transport carrier function, its regulation and coupling to metabolism, can be selectively investigated dissociated from metabolism and in the presence of a defined electrochemical ion gradient driving force, using the single internal compartment system provided by vesiculated surface membranes. Vesicles isolated from nontransformed and Simian virus 40-transformed mouse fibroblast cultures catalyzed carrier-mediated transport of several neutral amino acids into an osmotically-sensitive intravesicular space without detectable metabolic conversion of substrate. When a Na⁺ gradient, external Na⁺ > internal Na⁺, was artifically imposed across vesicle membranes, accumulation of several neutral amino acids achieved apparent intravesicular concentrations 6- to 9-fold above their external concentrations. Na⁺-stimulated alanine transport activity accompanied plasma membrane material during subcellular fractionation procedures. Competitive interactions among several neutral amino acids for Na⁺-stimulated transport into vesicles and inactivation studies indicated that at least 3 separate transport systems with specificity properties previously defined for neutral amino acid transport in Ehrlich ascites cells were functional in vesicles from mouse fibroblasts: the A system, the L system and a glycine transport system. The pH profiles and apparent K_m values for alanine and 2-aminoisobutyric acid transport into vesicles were those expected of components of the corresponding cellular uptake system. Several observations indicated that both a Na⁺ chemical concentration gradient and an electrical membrane potential contribute to the total driving force for active amino acid transport via the A system and the glycine system. Both the initial rate and quasi-steady-state of accumulation were stimulated as a function of increasing concentrations of Na⁺ applied as a gradient (external > internal) across the membrane. This stimulation was independent of endogenous Na⁺, K⁺-ATPase activity in vesicles and was diminished by monensin or by preincubation of vesicles with Na⁺. The apparent K_m for transport of alanine and 2-aminoisobutyric acid was decreased as a function of Na⁺ concentration. Similarly, in the presence of a standard initial Na⁺ gradient, quasi-steady-state alanine accumulation in vesicles increased as a function of increasing magnitudes of interior-negative membrane potential imposed across the membrane by means of K⁺ diffusion potentials (internal > external) in the presence of valinomycin; the magnitude of this electrical component was estimated by the apparent distributions of the freely permeant lipophilic cation triphenylme thylphosphonium ion. Alanine transport stimulation by charge asymmetry required Na⁺ and was blocked by the further addition of either nigericin or external K⁺. As a corollary, Na⁺-stimulated alanine transport was associated with an apparent depolarization, detectable as an increased labeled thiocyanate accumulation. Permeant anions stimulated Na⁺-coupled active transport of these amino acids but did not affect Na⁺-independent transport. Translocation of K⁺, H⁺, or anions did not appear to be directly involved in this transport mechanism. These characteristics support an electrogenic mechanism in which amino acid translocation is coupled t o an electrochemical Na⁺ gradient by formation of a positively charged complex, stoichiometry unspecified, of Na⁺, amino acid, and membrane component. Functional changes expressed in isolated membranes were observed t o accompany a change in cellular proliferative state or viral transformation. Vesicles from Simian virus 40-transformed cells exhibited an increased Vmax of Na⁺-stimulated 2-aminoisobutyric acid transport, as well as an increased capacity for steady-state accumulation of amino acids in response t o a standard Na⁺ gradient, relative t o vesicles from nontransformed cells. Density-inhibition of nontransformed cells was associated with a marked decrease in these parameters assayed in vesicles. Several possibilities for regulatory interactions involving gradient-coupled transport systems are discussed.     

Steroid hormones and plant growth and development

The occurrence of steroid hormones in plants is briefly reviewed. Their effects on plant growth, development and flowering are also considered.     

Incorporation of the gene for a cell-cell channel protein into transformed cells leads to normalization of growth

Summary Incorporation of the gene for connexin 43, a cell-cell channel protein of gap junction, into the genome of communication-deficient transformed mouse 10T1/2 cells restored junctional communication and inhibited growth. Growth was slowed, saturation density reduced and focus formation suppressed, and these effects were contingent on overexpression of the exogenous gene and the consequent enhancement of communication. In coculture with normal cells the growth of the connexin overexpressors was completely arrested, as these cells established strong communication with the normal ones. Thus, in culture by themselves or in coculture, the connexin overexpressor cells grew like normal cells. These results demonstrate that the cell-cell channel is instrumental in growth control; they are the expected behavior if the channel transmits cytoplasmic growth-regulatory signals.     

An improved approach for transformation of plant cells by microinjection: molecular and genetic analysis

A new culture method for the injection of tobacco mesophyll protoplasts has been established. The protoplasts are embedded in a thin layer of alginate and are nourished from the medium in the underlying basislayer. In the alginate layer the protoplasts regenerate to calli at a frequency of up to 80%. Embedded protoplasts can be selected either with 50 mg l⁻¹ kanamycin or 5 mg l⁻¹ paromomycin. Single resistant cells can be recovered from about 10 000 sensitive cells in one alginate layer. Injection of theneo gene (coding for neomycin phosphotransferase II) into protoplast derived single cells in the alginate layer results in kanamycin resistant colonies that can be regenerated to mature plants. These plants express the neomycin phosphotransferase as shown by enzyme activity assay. The integration of the transgene into the plant genome could be proved by Southern hybridization to high molecular weight DNA. With this culture method 100 cells can be injected per hour. Transformation frequencies range from 2 to 20%. In crossing experiments, it was shown that the foreign gene is transmitted to the next generation in a Mendelian fashion.     

Partial trisomies in two spontaneously arising long-lived human keratinocyte lines

Summary During experiments concerning the introduction of oncogenes into normal human keratinocytes, we observed long-lived colonies arising spontaneously at the same low frequency in control cultures as in those transfected with Ha-rasEJ or activated c-myc or both. Two of these were karyotyped early in their life span and showed additional chromosomal material on the short arm of chromosome 9 in one case and of chromosome 18 in the other, whereas the parental cells had a normal karyotype. This indicates the presence of a partial trisomy in each line, although the origin of the extra chromosomal material is not known. A similarly long-lived human keratinocyte line containing an isochromosome of the long arm of chromosome 8 has been described elsewhere. Together these results suggest that the spontaneous occurrence of long-lived lines is more common in human keratinocytes than in fibroblasts and that a triple dose of one or more genes may be the initial event in this process. This work was supported by grant CA16754 from the National Cancer Institute, Bethesda, MD.