A major chemotaxis gene cluster in Azospirillum brasilense and relationships between chemotaxis operons in alpha-proteobacteria

Azospirillum brasilense shows chemotaxis to a variety of nutrients and oxygen. Genes encoding the central signal transduction pathway in chemotaxis were identified by phenotypic complementation of generally non-chemotactic mutants. Sequencing of a DNA fragment, which complemented two different mutants, revealed a region of five open reading frames translated in one direction and encoding homologs of known genes comprising excitation and adaptation pathways for chemotaxis in other bacterial species. The major chemotaxis gene cluster appears to be essential for all known behavioral responses that direct swimming motility in A. brasilense. Phylogenetic and genomic analysis revealed three groups of chemotaxis operons in alpha-proteobacterial species and assigned the A. brasilense operon to one of them. Interestingly, operons that are shown to be major regulators of behavior in several alpha-proteobacterial species are not orthologous.     

Study of the first hours of microvinification by the use of osmotic stress-response genes as probes

When yeast cells are inoculated into grape must for vinification they find stress conditions because of osmolarity, which is due to very high sugar concentration, and pH lower than 4. In this work an analysis of the expression of three osmotic stress induced genes (GPD1, HSP12 and HSP104) under microvinification conditions is shown as a way to probe those stress situations and the regulatory mechanisms that control them. The results indicate that during the first hours of microvinification there is an increase in the GPDI mRNA levels with a maximum about one hour after inoculation, and a decrease in the amount of HSP12 and HSP104 mRNAs, although with differences between them. The RNA steady-state levels of all the genes considered, and in some cases the microvinification progress are significantly affected by the composition of the must (pH, nature of the osmotic agent and carbon source). These results point out the importance of the control of these parameters and the yeast molecular response during the first hours of vinification for an accurate winemaking process.     

Cardiovascular effects of 1,8-cineole,a terpenoid oxide present in many plant essential oils,in normotensive rats

The cardiovascular effects of i.v. treatment with 1,8-cineole, a monoterpenic oxide present in many plant essential oils, were investigated in normotensive rats. This study examined (i) whether the autonomic nervous system is involved in the mediation of 1,8-cineole-induced changes in mean aortic pressure (MAP) and heart rate (HR) and (ii) whether the hypotensive effects of 1,8-cineole could result from its vasodilatory effects directly upon vascular smooth muscle. In both pentobarbital-anesthetized and conscious, freely moving rats, bolus injections of 1,8-cineole (0.3-10 mg/kg, i.v.) elicited similar and dose-dependent decreases in MAP. Concomitantly, 1,8-cineole significantly decreased HR only at the highest dose (10 mg/kg). Pretreatment of anesthetized rats with bilateral vagotomy significantly reduced the bradycardic responses to 1,8-cineole (10 mg/kg) without affecting hypotension. In conscious rats, i.v. pretreatment with methylatropine (1 mg/kg), atenolol (1.5 mg/kg), or hexamethonium (30 mg/kg) had no significant effects on the 1,8-cineole-induced hypotension, while bradycardic responses to 1,8-cineole (10 mg/kg) were significantly reduced by methylatropine. In rat isolated thoracic aorta preparations, 1,8-cineole (0.006-2.6 mM) induced a concentration-dependent reduction of the contraction induced by potassium (60 mM). This is the first physiological evidence that i.v. treatment with 1,8-cineole in either anesthetized or conscious rats elicits hypotension; this effect seems related to an active vascular relaxation rather than withdrawal of sympathetic tone.     

Glyconeogenic pathway in isolated skeletal muscles of rats

Although the conversion of lactate to glycogen (glyconeogenesis) in muscle was demonstrated a long time ago, the biochemical reactions responsible for this process are still a controversial matter. In the present study, advantage was taken from the specific inhibition induced by phenylalanine on muscle pyruvate kinase (PK) to investigate the role of reverse PK activity in muscle glyconeogenesis. Addition of phenylalanine to the incubation medium of a preparation of isolated, intact skeletal muscles that maintain metabolic activity for several hours reduced by 50% the rate of incorporation of [14C]lactate or [14C]bicarbonate into muscle glycogen. Muscle extracts presented high levels of maximal activity of PK in the reverse direction, which was completely blocked in the presence of phenylalanine. In contrast, mercaptopicolinic acid, an inhibitor of phosphoenolpyruvate carboxykinase (PEPCK), did not affect the incorporation of 14C from either lactate or bicarbonate into muscle glycogen. Maximal PEPCK activity was much lower in muscle extracts than in gluconeogenic or glyceroneogenic tissues and was suppressed in the presence of mercaptopicolinic acid. The data suggest that a reversal of the metabolic flux through the reaction catalyzed by PK contributes to the accumulation of lactate-derived glycogen that occurs in skeletal muscle under certain physiological conditions.     

Inhibitory actions of eugenol on rat isolated ileum

The effects of eugenol (1-2000 microM) on rat isolated ileum were studied. Eugenol relaxed the basal tonus (IC50 83 microM) and the ileum precontracted with 60 mM KCl (IC50 162 microM), an action unaltered by 0.5 microM tetrodotoxin, 0.2 mM N(G)-nitro-L-arginine methyl ester, 0.5 mM hexamethonium, and 1 microM indomethacin. Eugenol did not alter the resting transmembrane potential (Em) of the longitudinal muscle layer under normal conditions (5.0 mM K+) or in depolarised tissues. Eugenol reversibly inhibited contractions induced by submaximal concentrations of acetylcholine (ACh) and K+ (40 mM) with IC50 values of approximately 228 and 237 microM, respectively. Eugenol blocked the component of ACh-induced contraction obtained in Ca(2+)-free solution (0.2 mM EGTA) or in the presence of nifedipine (1 microM). Our results suggest that eugenol induces relaxation of rat ileum by a direct action on smooth muscle via a mechanism largely independent of alterations of Em and extracellular Ca2+ influx.     

Role of the large cytoplasmic loop of the alpha 7 neuronal nicotinic acetylcholine receptor subunit in receptor expression and function

The role of the large intracellular loop of the nicotinic acetylcholine receptor (nAChR) alpha7 subunit in the expression of functional channels was studied. For this purpose, systematic deletions and substitutions were made throughout the loop and the ability of the mutated alpha7 subunits to support expression of functional nAChRs at the Xenopus oocyte membrane was tested. Surface nAChR expression was abolished upon removal of sequences at two regions, a 29-amino acid segment close to the N-terminus of the loop (amino acids 297-325) and adjacent to the third transmembrane region and an 11-amino acid segment near the fourth transmembrane region. Some residues (amino acids 317-322) within the 29 amino acids N-terminal segment could be substituted by others but not deleted without loss of expression, suggesting that a certain structure, determined by the number of amino acids rather than by their identity, has to be maintained in this region. The contiguous sequence M323 K324 R325 did not tolerate deletions and substitutions. Removal of the rest of the cytoplasmic loop was not deleterious; even higher expression levels (2-4-fold) were obtained upon large deletions of the loop (Delta399-432 and Delta339-370). High expression levels were observed provided that a minimal sequence of three amino acids (E371, G372, and M373) was present. In addition, some electrophysiological properties of mutant nAChRs were modified. Substitution of the EGM sequence by other protein segments produced a variety of effects, but, in general, insertions were not well tolerated, suggesting the existence of tight structural restrictions in the large cytoplasmic region of the rat alpha7 subunit.     

Catalytic phosphorylation of Na,K-ATPase drives the outward movement of its cation-binding H5-H6 hairpin

The Na,K-ATPase undergoes conformational transitions during its catalytic cycle that mediate energy transduction between the phosphorylation and cation-binding sites. Structure-function studies have shown that transmembrane segments H5 and H6 in the alpha subunit of the enzyme participate in cation binding and transport. The Ca-ATPase crystal structure indicates that the H5 helix extends into the cytoplasmic ATP binding domain, finishing 4-5 A from the phosphorylation site. Here, we test whether the phosphorylation of the Na,K-ATPase leads to conformational changes in the cation-binding H5-H6 hairpin. Using as background an enzyme where all wild-type Cys in the transmembrane region were replaced, Cys were introduced in the joining loop and extracellular ends of H5 and H6. Mutated proteins were expressed in COS cells and probed with Hg(2+), [2-(trimethylammonium)ethyl]methanethiosulfonate (MTSET), and biotin-maleimide, applied to the extracellular media while placing the cells in two different media (K-medium and Na-medium). We assumed that under these treatment conditions most of the enzyme would be in one of two predominant conformations: E1 (K-medium) and E2P (Na-medium). The extent of enzyme inactivation by Hg(2+) or MTSET treatment was dependent on the targeted position; i.e., proteins carrying Cys in the outermost positions were more affected by treatment. Moreover, in the case of proteins carrying Cys at positions 785, 787, and 797, driving the enzyme to phosphorylated conformations (Na-media) led to a larger inactivation. Similarly, biotinylation of introduced Cys was also influenced by the enzyme conformation, with a larger extent of modification after treatment of cells in the Na-medium (E2P form). These results can be explained by the enzyme phosphorylation driving the outward movement of the H5 helix. Thus, they provide experimental evidence for a structure-function mechanism where, via H5, enzyme phosphorylation leads to a conformational change at the cation-binding site and the consequent cation translocation.     

Sphingomyelinase cleavage of sphingomyelin in pure and mixed lipid membranes. Influence of the physical state of the sphingolipid

Sphingomyelin hydrolysis by sphingomyelinase is essential in regulating membrane levels of ceramide, a well-known metabolic signal. Since natural sphingomyelins have a gel-to-fluid transition temperature in the range of the physiological temperatures of mammals and birds, it is important to understand the influence of the physical state of the lipid on the enzyme activity. With that aim, large unilamellar vesicles consisting of pure egg sphingomyelin (gel-to-fluid crystalline transition temperature ca. 39 degrees C) were treated with sphingomyelinase in the temperature range 10-70 degrees C. The vesicles were also examined by differential scanning calorimetry (DSC). Shingomyelinase was active on pure sphingomyelin bilayers, leading to concomitant lipid hydrolysis, vesicle aggregation, and leakage of aqueous liposomal contents. Enzyme activity was found to be much higher when the substrate was in the fluid than when it was in the gel state. Sphingomyelinase activity was found to exhibit lag times, followed by bursts of activity. Lag times decreased markedly when the substrate went from the gel to the fluid state. When egg phosphatidylcholine, or egg phosphatidylethanolamine were included in the bilayer composition together with sphingomyelin, sphingomyelinase activity at 37 degrees C, that was negligible for the pure sphingolipid bilayers, was seen to increase with the proportion of glycerophospholipid, while the latency times became progressively shorter. A DSC study of the mixed-lipid vesicles revealed that both phosphatidylcholine and phosphatidyletanolamine decreased in a dose-dependent way the transition temperature of sphingomyelin. Thus, as those glycerophospholipids were added to the membrane composition, the proportion of sphingomyelin in the fluid state at 37 degrees C increased accordingly, in this way becoming amenable to rapid hydrolysis by the enzyme. Thus sphingomyelinase requires the substrate in bilayer form to be in the fluid state, irrespective of whether this is achieved through a thermotropic transition or by modulating bilayer composition.     

Thiol protecting agents and antioxidants inhibit the mitochondrial permeability transition promoted by etoposide: implications in the prevention of etoposide-induced apoptosis

Etoposide (VP-16) is known to promote cell apoptosis either in cancer or in normal cells as a side effect. This fact is preceded by the induction of several mitochondrial events, including increase in Bax/Bcl-2 ratio followed by cytochrome c release and consequent activation of caspase-9 and -3, reduction of ATP levels, depolarization of membrane potential (DeltaPsi) and rupture of the outer membrane. These events are apoptotic factors essentially associated with the induction of the mitochondrial permeability transition (MPT). VP-16 has been shown to stimulate the Ca2+-dependent MPT induction similarly to prooxidants and to promote apoptosis by oxidative stress mechanisms, which is prevented by glutathione (GSH) and N-acetylcysteine (NAC). Therefore, the aim of this work was to study the effects of antioxidants and thiol protecting agents on MPT promoted by VP-16, attempting to identify the underlying mechanisms on VP-16-induced apoptosis. The increased sensitivity of isolated mitochondria to Ca2+-induced swelling, Ca2+ release, depolarization of DeltaPsi and uncoupling of respiration promoted by VP-16, which are prevented by cyclosporine A proving that VP-16 induces the MPT, are also efficiently prevented by ascorbate, the primary reductant of the phenoxyl radicals produced by VP-16. The thiol reagents GSH, dithiothreitol and N-ethylmaleimide, which have been reported to prevent the MPT induction, also protect this event promoted by VP-16. The inhibition of the VP-16-induced MPT by antioxidants agrees with the prevention of etoposide-induced apoptosis by GSH and NAC and suggests the generation of oxidant species as a potential mechanism underlying the MPT that may trigger the release of mitochondrial apoptogenic factors responsible for apoptotic cascade activation.