Unusual pattern of bacterial ice nucleation gene evolution

Bacterial ice nucleation activity (INA+ phenotype) can be traced to the product of a single gene, ina. A remarkably sparse distribution of this phenotype within three bacterial genera indicates that the ina gene may have followed an unusual evolutionary path. Southern blot analyses, coupled with assays for ice-nucleating ability, revealed that within four bacterial species an ina gene is present in some strains but absent from others. Results of hybridization experiments using DNA fragments that flank the ina gene suggested that the genotypic dimorphism of ina may be anomalous. A phylogenetic analysis of 16S ribosomal RNA gene sequences from a total of 14 ina+ and ina- bacterial strains indicated that the ina+ bacteria are not monophyletic but instead phylogenetically interspersed among ina- bacteria. The relationships of ina+ bacteria inferred from ina sequence did not coincide with those inferred from the 16S data. These results suggest the possibility of horizontal transfer in the evolution of bacterial ina genes.      

Peptide alkaloids as inhibitors of photophosphorylation in spinach chloroplasts

Photophosphorylation in isolated spinach chloroplasts was inhibitedby all 21 peptide alkaloids tested. Zizyphine A and B, adounetineZ, amphibine B, C and D and scutianine A inhibited the coupledbut not the uncoupled electron transport. The other peptidealkaloids stimulated nonphosphorylating electron flow behavinglike uncouplers. Aralionine A, lasiodine A and mucronine B werethe strongest inhibitors and uncouplers. Lasiodine A and homalinestimulated by several times the light-induced proton uptakeby chloroplasts. (Received January 20, 1977; )     

β-Decay and the origin of optical purity

Improving Keszthelyis simple model the evolutionary appearance of concentration difference of enanthiomeric compounds due to their differential decomposition by -rays is investigated taking into account the racemization as well. It is shown that if the difference in the cross sections is very small then the resulting concentration difference will never exceed the statistical fluctuations, while in the case of a sufficiently large difference in the cross sections the concentration difference can overgrow the statistical fluctuations in an evolutionary reasonable period of time. The relative difference of the concentrations, however, will be generally much smaller than that of the cross sections. Therefore some other, amplifying mechanism must be postulated in order to explain the optical purity of living beings.     

Sulphydryl groups in photosynthetic energy conservation. IV. Inhibition of the ATPase of chloroplast coupling factor 1 by sulphydryl reagents

1. o-Iodosobenzoate and 2,2′-dithio bis-(5-nitropyridine) inhibited by about fifty per cent the ATPase activity of heat-activated chloroplast coupling factor 1 only when present during the heating but were without effect when added before or after the activation. Reversion of this inhibition was only obtained by a second heat treatment with 10 mM dithioerythritol.2. The inhibition of the Ca²⁺-ATPase of coupling factor 1 by o-iodosobenzoate or 2,2′-dithio bis-(5-nitropyridine) was not additive with similar inhibitions obtained with the alkylating reagents iodoacetamide and N-ethylmaleimide.3. The heat-activated ATPase of o-iodosobenzoate-treated coupling factor 1 had a higher K_m for ATP, without modification of V. The modified enzyme was desensitized against the allosteric inhibitor ADP.     

NADP-malic enzyme from plants.

NADP-malic enzyme functions in plant metabolism as a decarboxylase of malate in the chloroplast or cytosol. It serves as a source of CO2 for photosynthesis in the bundle sheath chloroplasts of C4 plants and in the cytosol of Crassulacean acid metabolism plants, and as a source of NADPH and pyruvate in the cytosol of various tissues. Mg2+ or Mn2+ is required as a cofactor. The enzyme has a high specificity and low Km for NADP+. It exists as a tetramer which may undergo changes in oligomerization and exhibit hysteresis. Its kinetic properties vary depending on the compartmentation and function of the enzyme. The chloroplast form in C4 plants has a high pH optimum (pH 8) under high malate, which favours the tetramer, whereas lower pH (pH 7) favours the dimer form. Generally, other forms of the enzyme, which are thought to be cytosolic, have lower pH optima than the chloroplast enzyme. In a number of cases these forms have been shown to have allosteric properties with malate as a substrate. Chemical modifications of the plant enzyme suggest sulphydryl, histidine and arginine residues are required for catalysis. Primary sequence studies on the chloroplastic enzyme from C4 plants show significant similarities to cytosolic NADP-ME in plants and animals, including a sequence motif which is indicative of the NADP+ binding site. The possible origin of the chloroplast form of the enzyme is discussed.     

Effects of ICI 182780 on estrogen receptor expression,fluid absorption and sperm motility in the epididymis of the bonnet monkey

Background  

The importance of estrogen in regulation of fluid absorption and sperm maturation in the rodent epididymis has been established from studies on estrogen receptor-alpha knockout mice. However, functional studies on the role of estrogen in primate epididymis have been few. The main objective of this study was therefore to extend these observations and systematically analyze the presence and function of estrogen receptors in modulating the function of the primate epididymis, using the bonnet monkey (Macaca radiata) as a model system.     

Compartmentation of photosynthesis in cells and tissues of C(4) plants

Critical to defining photosynthesis in C(4) plants is understanding the intercellular and intracellular compartmentation of enzymes between mesophyll and bundle sheath cells in the leaf. This includes enzymes of the C(4) cycle (including three subtypes), the C(3) pathway and photorespiration. The current state of knowledge of this compartmentation is a consequence of the development and application of different techniques over the past three decades. Initial studies led to some alternative hypotheses on the mechanism of C(4) photosynthesis, and some controversy over the compartmentation of enzymes. The development of methods for separating mesophyll and bundle sheath cells provided convincing evidence on intercellular compartmentation of the key components of the C(4) pathway. Studies on the intracellular compartmentation of enzymes between organelles and the cytosol were facilitated by the isolation of mesophyll and bundle sheath protoplasts, which can be fractionated gently while maintaining organelle integrity. Now, the ability to determine localization of photosynthetic enzymes conclusively, through in situ immunolocalization by confocal light microscopy and transmission electron microscopy, is providing further insight into the mechanism of C(4) photosynthesis and its evolution. Currently, immunological, ultrastructural and cytochemical studies are revealing relationships between anatomical arrangements and photosynthetic mechanisms which are probably related to environmental factors associated with evolution of these plants. This includes interesting variations in the C(4) syndrome in leaves and cotyledons of species in the tribe Salsoleae of the family Chenopodiaceae, in relation to evolution and ecology. Thus, analysis of structure-function relationships using modern techniques is a very powerful approach to understanding evolution and regulation of the photosynthetic carbon reduction mechanisms.     

Peach (Prunus persica) fruit response to anoxia: reversible ripening delay and biochemical changes

The use of modified atmospheres has been successfully applied in different fruits to delay the ripening process and to prevent physiological disorders. In addition, during normal ripening, hypoxic areas are generated inside the fruit; moreover, anaerobic conditions may also arise during fruit post-harvest storage and handling. In consequence, the fruit is an interesting model to analyze the metabolic modifications due to changes in oxygen levels. In this work, a 72 h anoxic treatment by using an N(2) storage atmosphere was applied to peaches (Prunus persica L. Batsch) after harvest. Ripening was effectively delayed in treated fruits, preventing fruit softening, color changes and ethylene production. Metabolic changes induced by anoxia included induction of fermentative pathways, glycolysis and enzymes involved in both sucrose synthesis and degradation. Sucrose, fructose and glucose contents remained unchanged in treated fruit, probably due to sucrose cycling. Sorbitol was not consumed and citrate was increased, correlating with citric acid cycle impairment due to O(2) deprivation. Malate content was not affected, indicating compensation in the reactions producing and consuming malate. Changes in malic enzymes and pyruvate orthophosphate dikinase may provide pyruvate for fermentation or even act to regenerate NADP. After fruit transfer to aerobic conditions, no signs of post-anoxia injury were observed and metabolic changes were reversed, with the exception of acetaldehyde levels. The results obtained indicate that peach fruit is an organ with a high capacity for anoxic tolerance, which is in accord with the presence of hypoxic areas inside fruits and the fact that hypoxic pre-treatment improves tolerance to subsequent anoxia.