Relationship between ion requirements for respiration and membrane transport in a marine bacterium.

Intact cells of the marine bacterium Alteromonas haloplanktis 214 oxidized NADH, added to the suspending medium, by a process which was stimulated by Na+ or Li+ but not K+. Toluene-treated cells oxidized NADH at three times the rate of untreated cells by a mechanism activated by Na+ but not by Li+ or K+. In the latter reaction, K+ spared the requirement for Na+. Intact cells of A. haloplanktis oxidized ethanol by a mechanism stimulated by either Na+ or Li+. The uptake of alpha-aminoisobutyric acid by intact cells of A. haloplanktis in the presence of either NADH or ethanol as an oxidizable substrate required Na+, and neither Li+ nor K+ could replace it. The results indicate that exogenous and endogenous NADH and ethanol are oxidized by A. haloplanktis by processes distinguishable from one another by their requirements for alkali metal ions and from the ion requirements for membrane transport. Intact cells of Vibrio natriegens and Photobacterium phosphoreum oxidized NADH, added externally, by an Na+-activated process, and intact cells of Vibrio fischeri oxidized NADH, added externally, by a K+-activated process. Toluene treatment caused the cells of all three organisms to oxidize NADH at much faster rates than untreated cells by mechanisms which were activated by Na+ and spared by K+.     

Insertion mutations in the dam gene of Escherichia coli K-12

The dam gene of E. coli can be inactivated by insertion of Tn9 or Mud phage. Strains bearing these mutations are viable indicating that the dam gene product is dispensable.     

Effects of hyperoxia on composition and rate of synthesis of fatty acids in Escherichia coli

Growth of and fatty acid synthesis in Escherichia coli were inhibited by oxygen at partial pressures above 1 atm and were prevented by exposure to oxygen at 4.2 atm on membranes incubated on a minimal medium. Growth and fatty acid synthesis returned to control rates when cells were removed from hyperoxia to air. The spectrum of fatty acids produced was unchanged by oxygen at pressures which reduced the rate of synthesis. In situ fatty acids were stable to oxygen at pressures which prevented growth and synthesis. Reinitiation of synthesis after complete inhibition in hyperoxia occurred without production of aberrant fatty acids. Fatty acid synthetase specific activity was virtually unchanged, compared with air controls, in cells exposed either to 3.2 or to 15.2 atm of oxygen. The spectrum of fatty acids synthesized by cell-free extracts during incubation in 4.2 atm of oxygen was not different from air-incubated controls. Synthetase assays included added NADPH, acyl carrier protein, mercaptoethanol, and malonyl coenzyme A; hence, damage, other than reversible sulfhydryl oxidation, to the apoenzymes of synthetase was ruled out.     

Freezing of nonwoody plant tissues. III. Videotape micrography and the correlation between individual cellular freezing events and temperature changes in the surrounding tissue

A new technique was developed for the observation and recording on videotape of thermal and microscopic changes that occur simultaneously during the freezing of cucumber tissue. The freezing process occurs in two steps. Nucleation and growth of ice crystals in the continuous extracellular liquid phase is followed by nucleation and growth of ice crystals in individual supercooled cells. The freezing of cells in rapid succession causes the average temperature to remain constant for a short time. This mechanism explains the second freezing plateau found in most plant tissue freezing curves.     

Rates of RNA synthesis during early embryogenesis in Drosophila melanogaster

We determined the absolute rates of RNA synthesis during embryogenesis in Drosophila melanogaster by measuring the incorporation of ³H-5-orotic acid into RNA, and the specific activity of the UTP pool. Initially (preblastoderm) the rate of RNA synthesis is relatively high, but declines to a lower level by gastrulation. The data suggest that RNA synthesis is initiated during very early embryogenesis.     

OBSERVATIONS ON THE RELATIONSHIP OF THE GOLGI APPARATUS TO WALL FORMATION IN THE MARINE CHRYSOPHYCEAN ALGA, PLEUROCHRYSIS SCHERFFELII PRINGSHEIM

The role of the Golgi apparatus in wall formation of vegetative cells of a marine chrysophyte, Pleurochrysis scherffelii, is described. Wall fragments are synthesized within the cisternae of the Golgi apparatus. A single Golgi apparatus is always located at the cell periphery, and the distended cisternae are oriented toward the cell surface. A highly-ordered body found near the inflated cisternae is associated with spherical, membrane-bounded bodies which may be involved in the progressive degeneration of cisternal membranes which release wall fragments. Protoplast movement has been detected by time-lapse cinephotomicrography and is correlated at the ultrastructural level with change in positions of the Golgi cisternae. Wall-synthesizing capacity is greatest during transverse wall formation. Senescent cells lack a Golgi apparatus with inflated cisternae. In addition, wall fragments are not present in the Golgi cisternae at this stage. Zoosporogenesis results in a temporary loss of the wall-forming capacity of the Golgi apparatus; this activity then resumes with the formation of a different morphological entity, the scale. Preliminary quantitative measurements of the turnover capacity of the Golgi apparatus have been made. From these data it has been determined that between 41 and 82 Golgi generations are required to synthesize the cell wall of an actively growing cell; this estimate indicates that approximately one cisterna is produced every 2 min, provided the cell generation time is 3 days. The time-lapse cinephotomicrographic data confirm that the rate of production of Golgi cisternae is at least one cisterna every 2 min.