Information transmission in non-visual fingertip matching along a horizontal track in the median plane

Non-visually triggered arm movements over a horizontal table at shoulder height were analysed by an Information Theory approach according to a method suggested by Sakitt et al. (1983) and Sakitt (1980). The movement track was along the subject's median line and was indicated by a vertical metal ridge fixed to the table. The observer passively moved the subject's left index finger along the left side of the ridge to the target position. The blindfolded subject then had to move his right index finger along the right side of the ridge to match the left finger position. Direct contact between the two fingers was prevented by the ridge. We compared our results, which involve the transmission of information through the arm and shoulder joints of both arms, whith those of Sakitt et al. which involved just one elbow joint. We supplemented our experimental results with simulations and show that the value for the transmitted information, obtained using the method of analysis suggested by Sakitt et al., is very dependent upon the number of trials, and number and spacing of the targets. Sakitt et al. suggest that the Information Theory approach permits easy comparison between different tasks and different observers. Our results suggest that comparisons should be made with caution.     

Mechanism of Enhanced Immature Dengue Virus Attachment to Endosomal Membrane Induced by prM Antibody

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Do Plant Cells Secrete Exosomes Derived from Multivesicular Bodies?

Multivesicular bodies (MVBs) are spherical endosomal organelles containing small vesicles formed by inward budding of the limiting membrane into the endosomal lumen. In mammalian red cells and cells of immune system, MVBs fuse with the plasma membrane in an exocytic manner, leading to release their contents including internal vesicles into the extracellular space. These released vesicles are termed exosomes. Transmission electron microscopy studies have shown that paramural vesicles situated between the plasma membrane and the cell wall occur in various cell wall-associated processes and are similar to exosomes both in location and in morphology. Our recent studies have revealed that MVBs and paramural vesicles proliferate when cell wall appositions are rapidly deposited beneath fungal penetration attempts or during plugging of plasmodesmata between hypersensitive cells and their intact neighboring cells. This indicates a potential secretion of exosome-like vesicles into the extracellular space by fusion of MVBs with the plasma membrane. This MVB-mediated secretion pathway was proposed on the basis of pioneer studies of MVBs and paramural vesicles in plants some forty years ago. Here, we recall the attention to the occurrence of MVB-mediated secretion of exosomes in plants.Key Words: cell wall, endocytosis, endosome, exocytosis, exosome, multivesicular body, paramural bodyMultivesicular bodies (MVBs) are spherical endosomal organelles containing a number of small vesicles formed by inward budding of the limiting membrane into the endosomal lumen.¹ MVBs contain endocytosed cargoes and deliver them into lysosomal/vacuolar compartments for degradation. They also incorporate newly synthesized proteins destined for lysosomal/vacuolar compartments.² In mammalian cells of hematopoietic origin, endosomal MVBs function in removal of endocytosed surface proteins in an exocytic manner. They are redirected to the plasma membrane, where they release their contents including internal vesicles into the extracellular space by membrane fusion. The released vesicles are termed exosomes.³ During reticulocyte maturation to erythrocyte, a group of surface proteins, such as the transferrin receptor, become obsolete and are discarded via MVB-mediated secretion.³ Time-course transmission electron microscopy (TEM) first revealed that colloidal gold-transferrin was internalized into MVBs via receptor-mediated endocytosis and then transferrin together with its receptor were delivered into the extracellular space via the fusion of MVBs with the plasma membrane of reticulocytes.⁴ Some other cell types of hematopoietic origin, such as activated platelets, cytotoxic T cells and antigen-presenting cells, also secrete exosomes. Exosomes thus may play a role in various physiological processes other than discarding obsolete proteins.³Our recent TEM studies provided ultrastructural evidence on the enhanced vesicle trafficking in barley leaf cells attacked by the biotrophic powdery mildew fungus. Multivesicular compartments including MVBs, intravacuolar MVBs, and paramural bodies turned out to proliferate in intact host cells during formation of cell wall appositions (papilla response), in the hypersensitive response, and during accommodation of haustoria.^5,6 MVBs proliferated in the cytoplasm of haustorium-containing epidermal cells during compatible interactions and near sites of cell wall-associated oxidative microburst either during the papilla response or during the hypersensitive response. Because MVBs in plant cells have been demonstrated to be endosomal compartments,^7–9 they may participate in internalization of nutrients from the apoplast of intact haustorium-containing epidermal cells and sequestration of damaged membranes and deleterious materials originating from the oxidative microburst.^5,6 The presence of intravacuolar MVBs with double limiting membranes (Fig. 1A) indicates an engulfment of MVBs by the tonoplast and a vacuole-mediated autophagy of MVBs.^5,6 MVBs, as prevacuolar compartments in plant cells,⁹ thus probably deliver their contents into the central vacuole via both the fusion with the tonoplast and the engulfment by the tonoplast (Fig. 2A and B). On the other hand, paramural bodies, in which small vesicles are situated between the cell wall and the plasma membrane, were associated with cell wall appositions deposited beneath fungal penetration attempts (Fig. 1B) or around hypersensitive cells including sites of plugged plasmodesmata (Fig. 1C and D).^5,6 Because paramural vesicles are similar to exosomes both in location and in morphology, we speculated that MVBs fuse with the plasma membrane in an exocytic manner to form paramural bodies.^5,6 Endocytosed cell surface materials in endosomal MVBs may be reused and delivered together with newly synthesized materials in Golgi apparatus-derived vesicles to cell wall appositions, which are deposited rapidly to prevent fungal penetration (Fig. 2A) or to contain hypersensitive cell death (Fig. 2B). MVBs thus may be driven along two distinct pathways to deliver their contents into either central vacuole or extracellular space.Open in a separate windowFigure 1Multivesicular compartments in intact cells in barley leaves attacked by the barley powdery mildew fungus. (A) An intravacuolar multivesicular body (MVB) with double limiting membranes in an intact epidermal cell (EC) adjacent to a hypersensitive epidermal cell (EC*). The arrows point to the outer limiting membrane, which is seemingly derived from the tonoplast. Note that neighboring intravacuolar vesicles (in between two arrowheads) may result from degradation of double limiting membranes of intravacuolar MVBs or may be delivered into the vacuole by MVB-fusion with the tonoplast. (B) Paramural vesicles (arrowheads) in a paramural body associated with cell wall appositions (asterisk) deposited by an intact epidermal cell. (C) A multivesicular body (MVB) in contact with a paramural body (PMB) (a nonmedian section) associated with cell wall appositions (asterisk) deposited by an intact mesophyll cell adjacent to a hypersensitive mesophyll cell. Note that cell wall appositions deposit beside an intercellular space (IS). The arrows point to the tonoplast. (D) A paramural body (PMB) associated with cell wall appositions (asterisks) blocking plasmodesmata (in between two arrowheads) at the side of an intact mesophyll cell (MC) underlying a hypersensitive epidermal cell (EC*). The arrows point to the tonoplast. CV, central vacuole; CW, cell wall; MB, microbody. Bars, 1µm.Open in a separate windowFigure 2Hypothetical diagram of delivery of endocytosed cell surface materials via MVBs into the central vacuole or the extracellular space where intact barley cells deposit cell wall appositions. (A) Deposition of cell wall appositions (asterisk) beneath powdery mildew penetration attempts. AGT, appressorial germ tube; PP, penetration peg. (B) Deposition of cell wall appositions (asterisks) against constricted plasmodesmata (PD) between a hypersensitive epidermal cell (EC) penetrated by the powdery mildew fungus and an underlying mesophyll cell (MC). H, haustorium. Arrows and numbers show pathways of vesicle trafficking. 1, Secretion of Golgi-derived vesicles containing newly synthesized materials; G, Golgi body; TGN, trans-Golgi network; 2, Endocytosis of cell surface materials from coated pits (coated open circles) via coated vesicles (coated circles) to multivesicular bodies (MVB); 3, Delivery of endocytosed materials for degradation inside the central vacuole (CV) via membrane fusion between MVBs and the tonoplast (T); small broken circles, vesicles in degradation; 4, Delivery of endocytosed materials for degradation inside the central vacuole via engulfment of MVBs by the tonoplast; large broken circles; MVB limiting membranes in degradation; 5, delivery of endocytosed materials into the extracellular space for deposition of cell wall appositions (asterisks) via membrane fusion between MVBs and the plasma membrane (PM). CW, cell wall; PMB, paramural body. PD0, 1, 2, 3 and 4 represent stages of plugging plasmodesmata. PD0, open plasmodesmata between two intact mesophyll cells (MC) subjacent to the hypersensitive epidermal cell (EC); PD1, constriction of plasmodesmata by callose (grey dots) deposition at plasmodesmal neck region; PD2, constricted plasmodesmata associated with plasmodesma-targeted secretion; PD3, further blocking of plasmodesmata by deposition of cell wall appositions; PD4, completely blocked plasmodesmata.Earlier than the discovery in animal cell systems,⁴ it was proposed in two independent papers in 1967 that the fusion of MVBs with the plasma membrane might result in the release of small vesicles into the extracellular space in fungi and in higher plants.^10,11 Several lines of evidence support the occurrence of MVB-mediated secretion of exosome-like vesicles in plants. First, vesicles of the same morphology as MVB internal vesicles have been observed in extracellular spaces or paramural spaces in various types of plant cells in various plant species by TEM.¹² An early study on endocytosis by soybean protoplasts also showed small extracellular vesicles attaching on the plasma membrane.⁸ Second, cooccurrence of MVBs and paramural vesicles has been observed in processes of cell proliferation, cell differentiation, and cell response to abiotic and biotic stress. Examples are cell plate formation,^13,14 secondary wall thickening,^15,16 cold hardness,^17,18 and deposition of cell wall appositions upon pathogen attack.^5,6,19–21 Third, identical molecular components, such as arabinogalactan proteins^22,23 and peroxidases,⁶ have been immunolocalized in both MVBs and paramural bodies. Despite these pieces of evidence, a conclusive demonstration of MVB-mediated secretion of exosomes in plants requires further exploration.The presently available experimental systems, approaches, and membrane markers may allow future demonstration of MVB-mediated secretion of exosomes in plants. Recent in vivo real-time observation and colocalization of cell surface and endosomal markers have already revealed that endosomes filled with endocytosed preexisting cell wall and plasma membrane materials are rapidly delivered to cytokinetic spaces to form cell plates in dividing tobacco, Arabidopsis, and maize cells.²⁴ Because TEM observed paramural bodies attaching to cell plates¹³ and MVBs in the vicinity of cell plates during all stages of cell plate formation,^14,25,26 MVBs and paramural bodies may participate in delivery of endocytosed building blocks to cell plates. Jiang''s and Robinson''s labs together developed a transgenic tobacco BY-2 cell line stably expressing a YFP-labeled vacuolar sorting receptor protein and antibodies against the vacuolar sorting receptor protein localized to the limiting membrane of MVBs.⁹ These tools together with live cell imaging and immunoelectron microscopy may allow visualization of MVB-fusion to the new plasma membrane, of vacuolar sorting receptors in both the limiting membrane of MVBs and the new plasma membrane, and of identical cell plate components in both internal vesicles of MVBs and paramural vesicles.In spite of obvious differences in plant and animal cytokinesis, the generation of cell plates by cell-plate-directed fusion of endosomes resembles the plugging of midbody canals by midbody-directed endosomes to separate daughter cells at the terminal phase of animal cytokinesis.²⁷ Likely, functional similarities of the fusion between endosomal MVBs and the plasma membrane to eliminate unwanted cell contents may also exist in maturation of mammalian red blood cells and plant sieve elements in the sense that the fusion of MVBs with the plasma membrane may occur during maturation of the latter.²⁸ On the other hand, although plant cells may secrete MVB-derived exosomes in defense response upon pathogen attack,^5,6 plant cell walls rule out the direct intercellular communication during the immune response mediated by exosomes in the circulation of mammals.³ In contrast, plasmodesma-directed secretion of exosomes would block the cell-to-cell communication between hypersensitive cells and their neighboring cells during hypersensitive response.⁵ Further exploration will lead us to a better understanding of similarities and differences of exosome secretion between plants and animals.     

RNA: Prebiotic Product,or Biotic Invention?

Spectacular advances in structural and molecular biology have added support to the 'RNA world' hypothesis, and provide a mandate for chemistry to explain how RNA might have been generated prebiotically on the early earth. Difficulties in achieving a prebiotically plausible synthesis of RNA, however, have led many to ponder the question posed in the title of this paper. Herein, we review recent experimental work on the assembly of potential RNA precursors, focusing on methods for stereoselective C-C bond construction by aldolisation and related processes. This chemistry is presented in the context of a broader picture of the potential constitutional self-assembly of RNA. Finally, the relative accessibility of RNA and alternative nucleic acids is considered.     

Evaporative cooling feature selection for genotypic data involving interactions

MOTIVATION: The development of genome-wide capabilities for genotyping has led to the practical problem of identifying the minimum subset of genetic variants relevant to the classification of a phenotype. This challenge is especially difficult in the presence of attribute interactions, noise and small sample size. METHODS: Analogous to the physical mechanism of evaporation, we introduce an evaporative cooling (EC) feature selection algorithm that seeks to obtain a subset of attributes with the optimum information temperature (i.e. the least noise). EC uses an attribute quality measure analogous to thermodynamic free energy that combines Relief-F and mutual information to evaporate (i.e. remove) noise features, leaving behind a subset of attributes that contain DNA sequence variations associated with a given phenotype. RESULTS: EC is able to identify functional sequence variations that involve interactions (epistasis) between other sequence variations that influence their association with the phenotype. This ability is demonstrated on simulated genotypic data with attribute interactions and on real genotypic data from individuals who experienced adverse events following smallpox vaccination. The EC formalism allows us to combine information entropy, energy and temperature into a single information free energy attribute quality measure that balances interaction and main effects. AVAILABILITY: Open source software, written in Java, is freely available upon request.     

Design of Protein Multi-specificity Using an Independent Sequence Search Reduces the Barrier to Low Energy Sequences

Computational protein design has found great success in engineering proteins for thermodynamic stability, binding specificity, or enzymatic activity in a ‘single state’ design (SSD) paradigm. Multi-specificity design (MSD), on the other hand, involves considering the stability of multiple protein states simultaneously. We have developed a novel MSD algorithm, which we refer to as REstrained CONvergence in multi-specificity design (RECON). The algorithm allows each state to adopt its own sequence throughout the design process rather than enforcing a single sequence on all states. Convergence to a single sequence is encouraged through an incrementally increasing convergence restraint for corresponding positions. Compared to MSD algorithms that enforce (constrain) an identical sequence on all states the energy landscape is simplified, which accelerates the search drastically. As a result, RECON can readily be used in simulations with a flexible protein backbone. We have benchmarked RECON on two design tasks. First, we designed antibodies derived from a common germline gene against their diverse targets to assess recovery of the germline, polyspecific sequence. Second, we design “promiscuous”, polyspecific proteins against all binding partners and measure recovery of the native sequence. We show that RECON is able to efficiently recover native-like, biologically relevant sequences in this diverse set of protein complexes.     

Human respiratory syncytial virus nucleoprotein and inclusion bodies antagonize the innate immune response mediated by MDA5 and MAVS

Currently, the spatial distribution of human respiratory syncytial virus (hRSV) proteins and RNAs in infected cells is still under investigation, with many unanswered questions regarding the interaction of virus-induced structures and the innate immune system. Very few studies of hRSV have used subcellular imaging as a means to explore the changes in localization of retinoic-acid-inducible gene-I (RIG-I)-like receptors or the mitochondrial antiviral signaling (MAVS) protein, in response to the infection and formation of viral structures. In this investigation, we found that both RIG-I and melanoma differentiation-associated gene 5 (MDA5) colocalized with viral genomic RNA and the nucleoprotein (N) as early as 6 h postinfection (hpi). By 12 hpi, MDA5 and MAVS were observed within large viral inclusion bodies (IB). We used a proximity ligation assay (PLA) and determined that the N protein was in close proximity to MDA5 and MAVS in IBs throughout the course of the infection. Similar results were found with the transient coexpression of N and the phosphoprotein (P). Additionally, we demonstrated that the localization of MDA5 and MAVS in IBs inhibited the expression of interferon β mRNA 27-fold following Newcastle disease virus infection. From these data, we concluded that the N likely interacts with MDA5, is in close proximity to MAVS, and localizes these molecules within IBs in order to attenuate the interferon response. To our knowledge, this is the first report of a specific function for hRSV IBs and of the hRSV N protein as a modulator of the innate immune response.     

Frasnian vertebrate taphonomy and sedimentology of macrofossil concentrations from the Langsēde Cliff,Latvia

Luk?evi?s, E., Ahlberg, P.E., Stinkulis, ?., Vasi?kova, J. & Zupi??, I. 2011: Frasnian vertebrate taphonomy and sedimentology of macrofossil concentrations from the Langsēde Cliff, Latvia. Lethaia, Vol. 45, pp. 356–370. The siliciclastic sequence of the Upper Devonian of Kurzeme, Western Latvia, is renowned for abundant vertebrate fossils, including the stem tetrapods Obruchevichthys gracilis and Ventastega curonica. During the first detailed taphonomic study of the vertebrate assemblage from the Ogre Formation cropping out at the Langsēde Cliff, Imula River, abundant vertebrate remains have been examined and identified as belonging to one psammosteid, two acanthodian and three sarcopterygian genera; the placoderm Bothriolepis maxima dominates the assemblage. Besides fully disarticulated placoderm and psammosteid plates, separate sarcopterygian scales and teeth, and acanthodian spines, partly articulated specimens including complete distal segments of Bothriolepis pectoral fins, Bothriolepis head shields and sarcopterygian lower jaws have been found. The size distribution of the placoderm bones demonstrates that the individuals within the assemblage are of approximately uniform age. Distinct zones have been traced within the horizontal distribution of the bones. These linear zones are almost perpendicular to the dominant dip azimuth of the cross‐beds and ripple‐laminae and most probably correspond to the depressions between subaqueous dunes. Concavity ratio varies significantly within the excavation area. The degree of fragmentation of the bones and disarticulation of the skeletons suggest that the carcasses were reworked and slightly transported before burial. Sedimentological data suggest deposition in a shallow marine environment under the influence of rapid currents. The fossiliferous bed consists of a basal bone conglomerate covered by a cross‐stratified sandstone with mud drapes, which is in turn overlain by ripple laminated sandstone, indicating the bones were buried by the gradual infilling of a tidal channel. All the Middle–Upper Devonian vertebrate bone‐beds from Latvia are associated with sandy to clayey deposits and have been formed in a sea‐coastal zone during rapid sedimentation episodes, but differ in fossil abundance and degree of preservation. □Agnathans, Devonian, facies analysis, fish, fossil assemblage, palaeoenvironment.     

Lead optimization of 2-(piperidin-3-yl)-1H-benzimidazoles: identification of 2-morpholin- and 2-thiomorpholin-2-yl-1H-benzimidazoles as selective and CNS penetrating H₁-antihistamines for insomnia

The structure-activity relationships of 2-(piperidin-3-yl)-1H-benzimidazoles, 2-morpholine and 2-thiomorpholin-2-yl-1H-benzimidazoles are described. In the lead optimization process, the pK(a) and/or logP of benzimidazole analogs were reduced either by attachment of polar substituents to the piperidine nitrogen or incorporation of heteroatoms into the piperidine heterocycle. Compounds 9a and 9b in the morpholine series and 10g in the thiomorpholine series demonstrated improved selectivity and CNS profiles compared to lead compound 2 and these are potential candidates for evaluation as sedative hypnotics.     

Equine sperm membrane phase behavior: the effects of lipid-based cryoprotectants

The plasma membrane of sperm can undergo lipid phase separation during freezing, resulting in irreversible damage to the cell. The objective of our study was to examine the membrane phase behavior of equine spermatozoa in the absence and presence of lipid-based cryoprotectants. Biophysical properties of sperm membranes were investigated with Fourier-transform infrared spectroscopy. Compared to fresh untreated sperm, postthaw untreated sperm showed extensive lipid phase separation and rearrangement. In contrast, postthaw sperm that were cryopreserved in egg phosphatidylcholine (egg PC)- or soy phosphatidylcholine (soy PC)-based diluents showed similar lipid phase behavior to that of fresh, untreated sperm. Studies with a deuterium-labeled PC lipid (POPCd-31) suggest that exogenous lipid from the diluents are strongly associated with the sperm membrane, and scanning electron microscopy images of treated sperm show the presence of lipid aggregates on the membrane surface. Thus, the exogenous lipid does not appear to be integrated into the sperm membrane after cryopreservation. When compared to a standard egg-yolk-based diluent (INRA 82), the soy and egg PC media preserved viability and motility equally well in postthaw sperm. A preliminary fertility study determined that sperm cryopreserved in the soy PC-based medium were capable of fertilization at the same rate as sperm frozen in the conventional INRA 82 medium. Our results show that pure lipid-based diluents can prevent membrane damage during cryopreservation and perform as well as a standard egg-yolk-based diluent in preserving sperm viability, motility, and fertility.