Sensory organs of the antennae and mouthparts of beetle larvae (Coleoptera)

The sensilla located on the antennae and maxillary and labial palps of the larvae of 64 beetle species from 22 families were studied using electron microscopy. The larvae of beetles living in different habitats and having different trophic specializations possess a uniform structure of the sensory organs. They are composed of two groups of sensilla on the apical and subapical segments of the antennae, one apical group of sensilla on both maxillary and labial palps, and one or several digitiform sensilla on the lateral surface of the maxillary and, occasionally, labial palp. The external morphology of the sensory organs is adaptive and represents modifications of the initial type. Band-shaped sensilla or placoid sensilla, clearly different from the initial sensory organs, appear in some taxa as rare exceptions, while other groups display either partial reduction of the receptor organs (Gyrinidae) or reduction of the cuticular parts of the sensilla (Cantharidae).     

Ligand-insensitive State of Cardiac ATP-sensitive K+ Channels : Basis for Channel Opening

The mechanism by which ATP-sensitive K⁺ (K_ATP) channels open in the presence of inhibitory concentrations of ATP remains unknown. Herein, using a four-state kinetic model, we found that the nucleotide diphosphate UDP directed cardiac K_ATP channels to operate within intraburst transitions. These transitions are not targeted by ATP, nor the structurally unrelated sulfonylurea glyburide, which inhibit channel opening by acting on interburst transitions. Therefore, the channel remained insensitive to ATP and glyburide in the presence of UDP. “Rundown” of channel activity decreased the efficacy with which UDP could direct and maintain the channel to operate within intraburst transitions. Under this condition, the channel was sensitive to inhibition by ATP and glyburide despite the presence of UDP. This behavior of the K_ATP channel could be accounted for by an allosteric model of ligand-channel interaction. Thus, the response of cardiac K_ATP channels towards inhibitory ligands is determined by the relative lifetime the channel spends in a ligand-sensitive versus -insensitive state. Interconversion between these two conformational states represents a novel basis for K_ATP channel opening in the presence of inhibitory concentrations of ATP in a cardiac cell.     

Death of the killer whale <Emphasis Type="Italic">Orsinus orca</Emphasis> from bacterial pneumonia in 2003

A killer whale was captured in Avacha Gulf (Kamchatka) on September 26, 2003. It was transported to the Utrish Sea Station (Black Sea) on October 6. However, the animal died in 13 days. As a result of microbiological analysis of the internal organs of dead animal, a bacterial culture was isolated that was identified as Pseudomonas aeruginosa. The infection by this opportunistic pathogen caused abscessing pneumonia that resulted in the death of the killer whale.     

ATP-sensitive potassium channels: metabolic sensing and cardioprotection.

The cardiovascular system operates under a wide scale of demands, ranging from conditions of rest to extreme stress. How the heart muscle matches rates of ATP production with utilization is an area of active investigation. ATP-sensitive potassium (K(ATP)) channels serve a critical role in the orchestration of myocardial energetic well-being. K(ATP) channel heteromultimers consist of inwardly-rectifying K(+) channel 6.2 and ATP-binding cassette sulfonylurea receptor 2A that translates local ATP/ADP levels, set by ATPases and phosphotransfer reactions, to the channel pore function. In cells in which the mobility of metabolites between intracellular microdomains is limited, coupling of phosphotransfer pathways with K(ATP) channels permits a high-fidelity transduction of nucleotide fluxes into changes in membrane excitability, matching energy demands with metabolic resources. This K(ATP) channel-dependent optimization of cardiac action potential duration preserves cellular energy balance at varying workloads. Mutations of K(ATP) channels result in disruption of the nucleotide signaling network and generate a stress-vulnerable phenotype with excessive susceptibility to injury, development of cardiomyopathy, and arrhythmia. Solving the mechanisms underlying the integration of K(ATP) channels into the cellular energy network will advance the understanding of endogenous cardioprotection and the development of strategies for the management of cardiovascular injury and disease progression.     

Synthesis of Oligonucleotide Derivatives with Aryl(trifluoromethyl)diazirine Moiety for the Photoaffinity Modification of Proteins and Nucleic Acids

1-(4-(3-(Trifluoromethyl)-3H-diazirin-3-yl)benzamido)-3-O-(4,4"-dimethoxytrityl)-2,3-propanediol phosphoramidite was synthesized and used as a modified unit in the automatic synthesis of oligodeoxyribonucleotides. Pentadecathymidylates with various numbers of 2,3-propanediol moieties substituted with aryl(trifluoromethyl)diazirinyl (ATFMD) were obtained, and the thermal stability of their duplexes with (dA)₁₅ were studied. One ATFMD-propanediol residue was shown to reduce the thermal stability of the duplex by 8–9°C. The irradiation of the ATFMD-containing duplexes by UV light with the wavelength of 350 nm was found to cause the cross-linking reaction of the ATFMD-containing strand with the complementary strand and the formation of the cross-linked duplexes. The photomodification efficiency was independent of the oligonucleotide sequence, with each ATFMD group providing for 5% cross-linking. The irradiation of an ATFMD-containing duplex, a substrate of the HIV-1 integrase, in the presence of this enzyme resulted in the covalent DNA–protein complex. The oligonucleotides with the 1-(4-(3-(trifluoromethyl)-3H-diazirin-3-yl)benzamido)-2,3-propanediol moiety in their chains can be used for the photoaffinity modification of both nucleic acids and proteins that recognize them.     

Molecular mechanisms of apoptosis. Structure of cytochrome c-cardiolipin complex

One of the functions of cytochrome c in living cells is the initiation of apoptosis by catalyzing lipid peroxidation in the inner mitochondrial membrane, which involves cytochrome c bound with acidic lipids, especially cardiolipin. In this paper the results of studies of cytochrome c-cardiolipin complex structure carried out by different authors mainly on unilamellar cardiolipin-containing phospholipid liposomes are critically analyzed. The principal conclusion from the published papers is that cytochrome c-cardiolipin complex is formed by attachment of a cytochrome c molecule to the membrane surface via electrostatic interactions and the subsequent penetration of one of the fatty-acid cardiolipin chains into the protein globule, this being associated with hydrophobic interactions that break the >Fe…S(Met80) coordinate bond and giving rise to appearance of cytochrome c peroxidase activity. Nevertheless, according to data obtained in our laboratory, cytochrome c and cardiolipin form spherical nanoparticles in which protein is surrounded by a monolayer of cardiolipin molecules. Under the action of cooperative forces, the protein in the globule expands greatly in volume, its conformation is modified, and the protein becomes a peroxidase. In extended membranes, such as giant monolayer liposomes, and very likely in biological membranes, the formation of nanospheres of cytochrome c-cardiolipin complex causes fusion of membrane sections and dramatic chaotization of the whole membrane structure. The subsequent disintegration of the outer mitochondrial membrane is accompanied by cytochrome c release from the mitochondria and triggering of a cascade of programmed cell death reactions.