Energy-dependent contraction of swollen heart mitochondria--activation by butacaine.

Butacaine and certain other local anesthetics markedly stimulate the rate, extent, and efficiency of respiration-dependent contraction of heart mitochondria in nitrate salts at alkaline pH. The local anesthetics also induce respiratory control associated with contraction (i.e., the elevated rate of respiration during contraction declines to a State 4-like controlled rate when contraction is complete) so that the reaction at alkaline pH closely resembles the rapid and highly efficient process seen at neutral pH. Respiration-dependent contraction appears to be an osmotic response to cation extrusion on an endogenous cation/H⁺ exchanger (G. P. Brierley, M. Jurkowitz, E. Chavez, and D. W. Jung, 1977, J. Biol. Chem.252, 7932–7939). At alkaline pH, net ion extrusion is slow and inefficient due to the elevated permeability of the membrane to monovalent cations through a putative uniport pathway. Butacaine and other local anesthetics seem to decrease influx-efflux cycling of cations at alkaline pH by restricting cation influx through this uniport. Passive swelling at pH 8.3 in nitrate salts indicates that the uniport reaction is sensitive to Ca²⁺ and has a cation-selectivity of Na⁺ > K⁺ > Li⁺. Butacaine does not inhibit passive swelling under these conditions but produces effects identical to those of classical uncouplers and consistent with increased H⁺ conductance and accelerated influx of cations by cation/H⁺ exchange in nonrespiring mitochondria. However, since contraction in respiring mitochondria is inhibited by uncouplers but stimulated by butacaine, it is apparent that butacaine is not an effective proton conductor in energized mitochondria.     

Transient receptor potential vanilloid 4 mediates protease activated receptor 2-induced sensitization of colonic afferent nerves and visceral hyperalgesia

Protease-activated receptor (PAR(2)) is expressed by nociceptive neurons and activated during inflammation by proteases from mast cells, the intestinal lumen, and the circulation. Agonists of PAR(2) cause hyperexcitability of intestinal sensory neurons and hyperalgesia to distensive stimuli by unknown mechanisms. We evaluated the role of the transient receptor potential vanilloid 4 (TRPV4) in PAR(2)-induced mechanical hyperalgesia of the mouse colon. Colonic sensory neurons, identified by retrograde tracing, expressed immunoreactive TRPV4, PAR(2), and calcitonin gene-related peptide and are thus implicated in nociception. To assess nociception, visceromotor responses (VMR) to colorectal distension (CRD) were measured by electromyography of abdominal muscles. In TRPV4(+/+) mice, intraluminal PAR(2) activating peptide (PAR(2)-AP) exacerbated VMR to graded CRD from 6-24 h, indicative of mechanical hyperalgesia. PAR(2)-induced hyperalgesia was not observed in TRPV4(-/-) mice. PAR(2)-AP evoked discharge of action potentials from colonic afferent neurons in TRPV4(+/+) mice, but not from TRPV4(-/-) mice. The TRPV4 agonists 5',6'-epoxyeicosatrienoic acid and 4alpha-phorbol 12,13-didecanoate stimulated discharge of action potentials in colonic afferent fibers and enhanced current responses recorded from retrogradely labeled colonic dorsal root ganglia neurons, confirming expression of functional TRPV4. PAR(2)-AP enhanced these responses, indicating sensitization of TRPV4. Thus TRPV4 is expressed by primary spinal afferent neurons innervating the colon. Activation of PAR(2) increases currents in these neurons, evokes discharge of action potentials from colonic afferent fibers, and induces mechanical hyperalgesia. These responses require the presence of functional TRPV4. Therefore, TRPV4 is required for PAR(2)-induced mechanical hyperalgesia and excitation of colonic afferent neurons.     

The mechanics of translocation: a molecular "spring-and-ratchet" system

The translation of genetic information into proteins is a fundamental process of life. Stepwise addition of amino acids to the growing polypeptide chain requires the coordinated movement of mRNA and tRNAs through the ribosome, a process known as translocation. Here, we review current understanding of the kinetics and mechanics of translocation, with particular emphasis on the structure of a functional mammalian ribosome stalled during translocation by an mRNA pseudoknot. In the context of a pseudoknot-stalled complex, the translocase EF-2 is seen to compress a hybrid-state tRNA into a strained conformation. We propose that this strain energy helps overcome the kinetic barrier to translocation and drives tRNA into the P-site, with EF-2 biasing this relaxation in one direction. The tRNA can thus be considered a molecular spring and EF-2 a Brownian ratchet in a "spring-and-ratchet" system within the translocation process.     

Prokaryotic-style frameshifting in a plant translation system: conservation of an unusual single-tRNA slippage event

Ribosomal frameshifting signals are found in mobile genetic elements, viruses and cellular genes of prokaryotes and eukaryotes. Typically they comprise a slippery sequence, X XXY YYZ, where the frameshift occurs, and a stimulatory mRNA element. Here we studied the influence of host translational environment and the identity of slippery sequence-decoding tRNAs on the frameshift mechanism. By expressing candidate signals in Escherichia coli, and in wheatgerm extracts depleted of endogenous tRNAs and supplemented with prokaryotic or eukaryotic tRNA populations, we show that when decoding AAG in the ribosomal A-site, E.coli tRNA(Lys) promotes a highly unusual single-tRNA slippage event in both prokaryotic and eukaryotic ribosomes. This event does not appear to require slippage of the adjacent P-site tRNA, although its identity is influential. Conversely, asparaginyl-tRNA promoted a dual slippage event in either system. Thus, the tRNAs themselves are the main determinants in the selection of single- or dual-tRNA slippage mechanisms. We also show for the first time that prokaryotic tRNA(Asn) is not inherently 'unslippery' and induces efficient frameshifting when in the context of a eukaryotic translation system.     

Progress in bioleaching: part B: applications of microbial processes by the minerals industries

This review presents developments and applications in bioleaching and mineral biooxidation since publication of a previous mini review in 2003 (Olson et al. Appl Microbiol Biotechnol 63:249–257, 2003). There have been discoveries of newly identified acidophilic microorganisms that have unique characteristics for effective bioleaching of sulfidic ores and concentrates. Progress has been made in understanding and developing bioleaching of copper from primary copper sulfide minerals, chalcopyrite, covellite, and enargite. These developments point to low oxidation–reduction potential in concert with thermophilic bacteria and archaea as a potential key to the leaching of these minerals. On the commercial front, heap bioleaching of nickel has been commissioned, and the mineral biooxidation pretreatment of sulfidic-refractory gold concentrates is increasingly used on a global scale to enhance precious metal recovery. New and larger stirred-tank reactors have been constructed since the 2003 review article. One biooxidation–heap process for pretreatment of sulfidic-refractory gold ores was also commercialized. A novel reductive approach to bioleaching nickel laterite minerals has been proposed.     

Note Sui Grani a Spighe Ramificate

Resumé

Chez les Blés branchus de l'espèce «turgidum» (Triticum turgidum compositum), il existe des sortes à thermostade plutôt froid (Blés d'hiver ou de semi-hiver) et des sortes à thermostade chaud, tièe ou «indifférent» (Blés de printemps).

Les Blés branchus de l'espèce «turgidum» apparaissent comme étant des plantes à photostade de jour long.

La plus ou moins grande rapidité de l'accomplissement du photostade, par rapport à la rapidité de l'assimilation des matières plastiques, détermine la structure, — non ramifiée ou ramifiée — de l'épi.     

SGO1 but not SGO2 is required for maintenance of centromere cohesion in Arabidopsis thaliana meiosis

Shugoshin is a protein conserved in eukaryotes and protects sister chromatid cohesion at centromeres in meiosis. In our study, we identified the homologs of SGO1 and SGO2 in Arabidopsis thaliana. We show that AtSGO1 is necessary for the maintenance of centromere cohesion in meiosis I since atsgo1 mutants display premature separation of sister chromatids starting from anaphase I. Furthermore, we show that the localization of the specific centromeric cohesin AtSYN1 is not affected in atsgo1, suggesting that SGO1 centromere cohesion maintenance is not mediated by protection of SYN1 from cleavage. Finally, we show that AtSGO2 is dispensable for both meiotic and mitotic cell progression in Arabidopsis.