Adenovirus-induced mutations at the hypoxanthine phosphoribosyltransferase locus of Chinese hamster cells.

Hpt-13 is a Chinese hamster cell line deficient in hypoxanthine phosphoribosyltransferase (EC 2.4.2.8) and sensitive to a medium containing 10(-4) M hypoxanthine, 5.5 X 10(-6) M aminopterin, and 10(-4) M thymidine. In this cell line there is a high incidence of cells resistant to this selective medium after an incubation with either ethyl methane sulfonate or adenovirus type 2 complete virions or their incomplete particles. The rate of reversion in the presence of these agents was 34-fold higher with ethyl methane sulfonate and 2.5- to 5.6-fold higher with adenovirus particles than the spontaneous rate of reversion. The revertant phenotypes were stable for many generations without selective pressure. All of the revertants tested recovered the hypoxanthine phosphoribosyltransferase activity. Most of them, however, carried an enzyme of lower activity and faster electrophoretic mobility than that of the wild type. The preferential reversion to this type of enzyme was observed among spontaneous revertants as well as among those induced by mutagenesis with ethyl methane sulfonate or exposure to viral particles. Our results suggest that adenovirus particles and ethyl methane sulfonate induce mutations at the hpt locus of Hpt-13 cells through similar mechanisms.     

Micro‐ and nano‐scale mineralogical characterization of Fe(II)‐oxidizing bacterial stalks

Neutrophilic, microaerobic Fe(II)‐oxidizing bacteria (FeOB) from marine and freshwater environments are known to generate twisted ribbon‐like organo‐mineral stalks. These structures, which are extracellularly precipitated, are susceptible to chemical influences in the environment once synthesized. In this paper, we characterize the minerals associated with freshwater FeOB stalks in order to evaluate key organo‐mineral mechanisms involved in biomineral formation. Micro‐Raman spectroscopy and Field Emission Scanning Electron Microscopy revealed that FeOB isolated from drinking water wells in Sweden produced stalks with ferrihydrite, lepidocrocite and goethite as main mineral components. Based on our observations made by micro‐Raman Spectroscopy, field emission scanning electron microscopy and scanning transmission electron microscope combined with electron energy‐loss spectroscopy, we propose a model that describes the crystal‐growth mechanism, the Fe‐oxidation state, and the mineralogical state of the stalks, as well as the biogenic contribution to these features. Our study suggests that the main crystal‐growth mechanism in stalks includes nanoparticle aggregation and dissolution/re‐precipitation reactions, which are dominant near the organic exopolymeric material produced by the microorganism and in the peripheral region of the stalk, respectively.     

Calcium gradients and exocytosis in bovine adrenal chromaffin cells

The relationship between the localized Ca(2+) concentration and depolarization-induced exocytosis was studied in patch-clamped adrenal chromaffin cells using pulsed-laser Ca(2+) imaging and membrane capacitance measurements. Short depolarizing voltage steps induced Ca(2+) gradients and small "synchronous" increases in capacitance during the pulses. Longer pulses increased the capacitance changes, which saturated at 16 fF, suggesting the presence of a small immediately releasable pool of fusion-ready vesicles. A Hill plot of the capacitance changes versus the estimated Ca(2+) concentration in a thin (100 nm) shell beneath the membrane gave n = 2.3 and K(d) = 1.4 microM. Repetitive stimulation elicited a more complex pattern of exocytosis: early pulses induced synchronous capacitance increases, but after five or more pulses there was facilitation of the synchronous responses and gradual increases in capacitance continued between pulses (asynchronous exocytosis) as the steep submembrane Ca(2+) gradients collapsed. Raising the pipette Ca(2+) concentration led to early facilitation of the synchronous response and early appearance of asynchronous exocytosis. We used this data to develop a kinetic model of depolarization-induced exocytosis, where Ca(2+)-dependent fusion of vesicles occurs from a small immediately releasable pool with an affinity of 1-2 microM and vesicles are mobilized to this pool in a Ca(2+)-dependent manner.