The respiratory metabolism of honey-bee colonies at low temperatures

Honey-bee colonies exposed to temperatures between 20° C and -39° C produced less CO₂ at 10° C than at higher or lower temperatures.

---

Zusammenfassung Honigbienenvölker wurden im Winter aus ihren Stöcken genommen und in galvanisierten Eisenbehältern (Tanks) Temperaturen zwischen 20 und -39° C ausgesetzt. Das Kohlendioxyd der aus den Behältern abgesogenen Luft wurde absorbiert und gewogen. Die CO₂-Produktion sank, wenn die Temperatur von 20 auf 10° erniedrigt wurde und stieg bei niederen Temperaturen wieder an. Diese Veränderungen verliefen in umgekehrter Richtung, wenn die Temperatur erhöht wurde.

     

Motor units at various temperatures

This review focuses on the effects of temperature on the functioning of the neuromuscular system. The changes in environmental temperature could affect the contractile acts in both ectotherms and endotherms by changing the amplitude and velocity of contractions and, accordingly, the mechanical work of skeletal muscles. In this study, we summarize the data on the effects of hypo- and hyperthermia on the supraspinal and peripheral components of regulation of the neuromuscular function.     

Kinetics of sunflower oil methanolysis at low temperatures

The kinetics of the sunflower oil methanolysis process was studied at lower temperatures (10-30 degrees C). The sigmoidal kinetics of the process was explained by the mass transfer controlled region in the initial heterogenous regime, followed by the chemical reaction controlled region in the pseudo-homogenous regime. A simple kinetic model, which did not require complex computation of the kinetic constants, was used for simulation of the TG conversion and the FAME formation in the latter regime: the fast irreversible second-order reaction was followed by the slow reversible second-order reaction close to the completion of the methanolysis reaction. The mass transfer was related to the drop size of the dispersed (methanol) phase, which reduced rapidly with the progress of the methanolysis reaction. This was attributed to the formation of the emulsifying agents stabilizing the emulsion of methanol drops into the oil.     

Microculture model studies on the effect of various gas atmospheres on microbial growth at different temperatures

A microculture technique, employing 96-well tissue culture plates in plastic bags, was used to test the effect of different gas atmospheres (vacuum, air, nitrogen, and carbon dioxide) on the growth of Escherichia coli, Bacillus macerans, Salmonella typhimurium, Candida albicans, Lactobacillus plantarum, Pseudomonas Acinetobacter/Moraxella -group, Brochothrix thermosphacta and Yersinia enterocolitica at 2, 6, and 20°C. In general, carbon dioxide was the most effective inhibitor. The inhibition increased with decreasing temperature. Only the combination of carbon dioxide and 2°C provided complete inhibition of Broch. thermosphacta and Y. enterocolitica.     

Microculture model studies on the effect of various gas atmospheres on microbial growth at different temperatures

A microculture technique, employing 96-well tissue culture plates in plastic bags, was used to test the effect of different gas atmospheres (vacuum, air, nitrogen, and carbon dioxide) on the growth of Escherichia coli, Bacillus macerans, Salmonella typhimurium. Candida albicans, Lactobacillus plantarum, Pseudomonas/Acinetobacter/moraxella-group, Brochothrix thermosphacta and Yersinia enterocolitica at 2, 6, and 20 degrees C. In general, carbon dioxide was the most effective inhibitor. The inhibition increased with decreasing temperature. Only the combination of carbon dioxide and 2 degrees C provided complete inhibition of Broch. thermosphacta and Y. enterocolitica.     

Effect of citrate on radial growth and conidiation of the mould Aspergillus nidulans

A mutation of the ctsA locus of Aspergillus nidulans affects both the radial growth and conidiation of the mould when grown in the presence of citrate. The ctsA locus was allocated to linkage group IV but it recombines freely with inoB2 and pyroA4 (which are also in linkage group IV). It is recessive in heterozygous diploids. A possible role for this gene in maintaining membrane integrity is discussed.The authors are with the Departamento de Genética, FMRP-USP, Av. Bandeirantes, 3900, 14049 Ribeirão Preto, SP., Brazil.     

Active plant growth at freezing temperatures

As a foundation for speculations in exobiology, we are attempting to understand plant responses to extreme environments on Earth. We have emphasized active plant growth at low temperatures and in response to ultraviolet light. We have studied the winter environment in the mountains near Logan, Utah and have found several plants that grow under the snow. We have measured chlorophyll synthesis, carbohydrate levels, and ion balances in these plants and established field experiments with hardy and nonhardy varieties of wheat. In the laboratory we have studied characteristics of three enzymes in two wheat varieties, finding a number of interesting differences in response to ultraviolet and low-temperature treatments. We have also examined cell ultrastructures of three grass species subjected to a range of temperatures. Chloroplasts were most affected at low temperatures, but other organelles were also influenced. Studies of ion balances substantiate the suggestion from ultrastructure work that membranes may exhibit the primary responses to low temperatures. Cytokinins are also implicated in the cold response. We are presently emphasizing the investigation of membranes. Lunar Science Institute Contribution.     

Lipid composition of tobacco cells cultivated at various temperatures

Tobacco cell suspensions were grown under controlled conditions to determine whether temperature aftected the fatty acid pattern of the cellular lipids. At any temperature ranging between 17° and 35°, the total fatty acid content and the levels of fatty acids or individual lipids varied during the growth period, The optimum temperature for lipid biosynthesis and polyunsaturated fatty acid accumulation was between 20° and 26°. Increase in the level of polyunsaturated fatty acids was associated with lower temperatures during the active cell division period.     

Kinetics of water loss from cells at subzero centigrade temperatures

A mathematical model is developed for the calculation of the kinetics of water loss from cells at subzero centigrade temperatures. In this model it is assumed that the cell surface membrane is permeable to water only, the protoplasm is a nonideal solution, the cells are spherical, and during the cooling process the cell temperature is not uniform inside the cell. It is also assumed that because of water loss due to cooling process the cell volume and the cell surface area reduce and the reductions in surface area and volume of the cell are functions of the amount of water loss from the cell. Based on this model, and for different conditions, the fractions of supercooled intracellular water remaining in the cells at various temperatures are calculated.It is shown that for cooling cells at subzero centigrade temperatures. (1) the consideration of Clausius-Clapeyron equation for vapor pressures of water and ice, instead of the exact vapor pressure relations, may produce errors in the prediction of the amount of water loss from the cells at high cooling rates only, (2) the assumption of intact cells will produce considerable deviation in the prediction of water loss from the cells as compared to the more realistic assumption of shrinkable cells, (3) the nonideality of protoplasm solution is very effective on the prediction of the amount of water loss from the cells, and (4) the assumption of uniform-temperature cells during the cooling process may be erroneous only for cells with small fractions of water in their protoplasms.