Freeze-fracturing and surface labelling of embryonic neural retina cells

Freeze-fracturing of dissociated and aggregating neural retina cells from 7-day chick embryos revealed on the inner faces (PF) of the cell membrane numerous particles 6–20 nm in size. In contrast, the PF faces of blebs and some of the lobopodia that project from the cell surface were practically devoid of such particles. However, the elongated filopodia that abound on these cells showed numerous particles on their PF faces. These regional differences in the distribution of particles on PF faces of these cells are interpreted as reflecting membrane activity that leads to the formation of blebs and lobopodia. The frequent presence of “pits” at the basis of blebs and lobopodia is described. It is suggested that the “pits” are associated with the formation of these membrane projections; they may represent anchoring sites for microfilaments and for microtubules involved in the dynamic structure of the cell surface. ConA-binding sites on these cells were studied by scanning electron microscopy, using labeling with hemocyanin. The distribution of these sites on different regions of the cell surface coincided with the regional differences in the distribution of the inner membrane particles.     

A Permanent Cell Viability Assay Using Alcian Blue

The alcian blue dye exclusion method for glutaraldehyde-fixed cells has been utilized with “centrifugal cytology” to prepare permanent records of the viability of individual cells present in suspensions. The viability of spleen cell suspensions separated by linear bovine serum albumin density gradient centrifugation has been measured with this method. Combined light and scanning electron microscopy of nonviable and viable cells demonstrated membrane alterations in alcian blue-stained nonviable cells, while viable cells were spherical and displayed uniform surface features.     

The utilization of bromodeoxyuridine incorporation into DNA for the analysis of cellular kinetics

Recently developed differential staining techniques based on the incorporation of bromodeoxyuridine (BUdR) into DNA permits the unequivocal identification of metaphase cells which have replicated once, twice, and three or more times. This technique has the potential of being utilized in the examination of kinetics of dividing cell populations. This potential is examined in a phytohemagglutinin-stimulated lymphocyte system. Determinations of the effect of increasing concentrations of BUdR on the distribution of metaphase cells between different generation cycles reveals no inhibition of cellular kinetics below 35 μM. The ability to distinguish third generation metaphase cells from subsequent generations is examined through the determination of “labelled” centromeric regions. The applicability of this system to current cellular kinetics is discussed.     

A two-stage model for concurrent sequences

Schneider and Davison [Schneider, S.M., Davison, M., 2005. Demarcated response sequences and the generalised matching law. Behav. Proc. 70, 51–61] showed that the generalised matching law applied to concurrent free-operant two-response sequences. When sufficient temporal spacing is required between the responses, however, neither the response-level nor the sequence-level forms of the generalised matching law provide good fits. An alternative “two-stage sensitivity” model with fewer free parameters features two types of sensitivity to the reinforcement contingencies on sequences. When temporal spacing between the responses is long, the “response distribution sensitivity” parameter describes sensitivity only of the individual responses to the sequence-level contingencies. At a threshold level, this sensitivity reaches a maximum. When spacing is shorter than threshold, the “response order sensitivity” parameter reflects a new sensitivity to the order of the responses within sequences. As this sensitivity approaches its maximum, sequence matching is achieved. For both stages, a changeover parameter describes bias against sequences that require changeovers between the two responses. The model fit data ranging from near-response matching with long minimum inter-response times (IRTs) to sequence matching with no minimum IRTs, using two species and a variety of sequence reinforcer distributions. Rats differed from pigeons in achieving sequence matching only at a nonzero minimum IRT. In a comparison based on pigeon data with no minimum IRT, the two-stage sensitivity model was more efficient than the generalised matching law according to the Akaike criterion. The logic of the model suggests a new way of understanding the mechanisms underlying behavioural units.     

Dynamics and Variability of Early Morphogenesis in the Loach according to Observations of Individual Developmental Trajectories

The dynamics and variability of quantitative morphological characters (morphological variables), which undergo changes upon epiboly, were studied by means of vital observations and measurements of developing loach (Misgurnus fossilis L.) embryos within equal time intervals. None of morphological variables, which characterize the dynamics of blastoderm shape, had monotonous dependence on time. In each individual embryo, the intervals of changes in morphological variables in the “normal” direction corresponding to the change of their mean values during the normal course of epiboly alternated with arrests, as well as with the changes of morphological variables in the reverse direction. The dynamics of morphological variables in time, which reflect the sequence of morphological states of the same embryo, and those of individual variations (variations of morphological states of different embryos on the same temporal section) had identical structure. This suggests instability of individual trajectories of morphogenesis or, strictly speaking, their actual absence. It was shown for the first time on the basis of analysis of individual trajectories of morphogenesis that its dynamics corresponded to so-called “determined chaos,” which was previously discussed only as a theoretical possibility. The data obtained suggest that upon approach to the equatorial area of the embryo, the blastoderm marginal zone was elongated in the longitudinal direction and contracted across the axis of its movement. As a result, a positive feedback arises between the cooperated cell movement and the change of shape of the surface, over which the cells move. This leads, due to unstable radial symmetry of this movement, to the formation of embryonic shield.__________Translated from Ontogenez, Vol. 36, No. 3, 2005, pp. 211–221.Original Russian Text Copyright © 2005 by Cherdantsev, Tsvetkova.     

Evolution of eye development in arthropods: phylogenetic aspects

The architecture of the adult arthropod visual system for many decades has contributed important character sets that are useful for reconstructing the phylogenetic relationships within this group. In the current paper we explore whether aspects of eye development can also contribute new arguments to the discussion of arthropod phylogeny. We review the current knowledge on eye formation in Trilobita, Xiphosura, Myriapoda, Hexapoda, and Crustacea. All euarthropod taxa share the motif of a proliferation zone at the side of the developing eye field that contributes new eye elements. Two major variations of this common motif can be distinguished: 1. The “row by row type” of Trilobita, Xiphosura, and Diplopoda. In this type, the proliferation zone at the side of the eye field generates new single, large elements with a high and variable cell number, which are added to the side of the eye and extend rows of existing eye elements. Cell proliferation, differentiation and ommatidial assembly seem to be separated in time but spatially confined within the precursors of the optic units which grow continuously once they are formed (intercalary growth). 2. The “morphogenetic front type” of eye formation in Crustacea + Hexapoda (Tetraconata). In this type, there is a clear temporal and spatial separation of the formation and differentiation processes. Proliferation and the initial steps of pattern formation take place in linear and parallel mitotic and morphogenetic fronts (the mitotic waves and the morphogenetic furrow/transition zone) and numerous but small new elements with a strictly fixed set of cells are added to the eye field. In Tetraconata, once formed, the individual ommatidia do not grow any more. Scutigeromorph chilopods take an intermediate position between these two major types. We suggest that the “row by row type” as seen in Trilobita, Xiphosura and Diplopoda represents the plesiomorphic developmental mode of eye formation from the euarthropod ground pattern whereas the “morphogenetic front type” is apomorphic for the Tetraconata. Our data are discussed with regard to two competing hypotheses on arthropod phylogeny, the “Tracheata” versus “Tetraconata” concept. The modes of eye development in Myriapoda is more parsimonious to explain in the Tetraconata hypothesis so that our data raise the possibility that myriapod eyes may not be secondarily reconstructed insect eyes as the prevailing hypothesis suggests.     

“Harpoon” Model for Cell–Cell Adhesion and Recognition of Target Cells by the Natural Killer Cells

The mechanism of recognition by natural killer (NK) cells is still unknown. A dynamic model is formulated describing recognition or NK-sensitive target cells (TCs) by NK cells of NK-like cells. This model does not assume the presence of the specific NK-receptor(s) on the membrane of NK cells and corresponding specific ligands on the NK-sensitive TCs. We suggest: (1) the expression of various kinds of “non-NK receptors” and corresponding ligands (counter-receptors) on the plasma membrane of the same NK cell and, possibly, of TCs (e.g. LFA-1 and ICAM-1-ICAM3, CD2 and LFA-3; receptors for TNF and corresponding ligand etc.); (2) the presence of multiple disorders in the organization of “extracellular matrix-surface membrane-submembrane cytoskeleton” assembly of the NK-sensitive TCs; (3) non-specific primary linking of NK cell with TCs, which induces a transfer of vesicles or membrane fragments from the NK surface to the target cell surface (and perhaps vice versa). These processes may also permit the transfer of many types of receptor and counter-receptor molecules from the surface of one conjugated cell to another by vesicles or membrane fragments. After transferral through the intercellular cleft, the free receptors and counter-receptors will be localized on both cell surfaces at the contact region between conjugated cells. By this model the NK cell can “harpoon” the TC and enhance the binding forces between cells up to the critical level and then switch on killing mechanisms for the TC. By means of this “harpoon” model of cell recognition, it seems possible to explain the nature of the wide polymorphism of TCs which are sensitive to the effect of NK and NK-like cells. A mathematical model of the NK cell cytotoxic reaction is described. The model describes many nonlinear peculiarities of the cytotoxic process and predicts some new phenomena. We suggest new approaches of manipulation of cell membranes which can transform NK-resistant target cells in NK sensitive cells and vice versa.     

Hierarchical pre-dispersal fitness assessment in a Mediterranean shrub plant

Under the concept of modularity, it is possible to recognise how seed production, as well as any other process affecting it, are hierarchically structured within fruits, within individual plants and within populations. In this work, we analysed the effects of pre-dispersal seed predation by insects upon a set of hierarchical levels in a population of the Mediterranean shrub plant Cistus ladanifer (“rock rose”) throughout a complete fruit-producing season (which takes place during the summer months). Almost all individual plants were predated, which implies that the effects of predation at the population level (regardless of the extent of predation within each individual) were virtually uniform. Within the individuals, however, the predation rate was close to a proportion of 0.5 (half of the fruits of each individual were predated), which indicates that this hierarchical level is likely to be subjected to a differential action of selection. Predation rates within the fruits showed an intermediate value (lower than that observed at the population level but higher than that at the individual level). According to these results, the pressure of phenotypic selection may therefore give rise to greater variation among fruits of the same individual than among seeds of the same fruit. In terms of the temporal patterns observed there was a large variation in the increments of predation along the fruiting season, which implies a high degree of heterogeneity in the temporal distribution of the effects of predation pressure on fitness. Besides its use in the specific example of the plant species studied in this work, the methodological procedure presented in this paper (integration of the temporal changes of different hierarchical levels) might be foreseen, in fact, as a useful tool for analysing the hierarchical structuring of fitness in modular organisms in general. This procedure allows to discriminate and integrate selection pressures and their effects across different phenotypic levels, from the infra-individual ones up to the population level.     

On necessary and sufficient conditions for group selection efficacy

The statement “group selection predominates over individual selection” is formulated within a class of patch-structured models. Conditions involving both “selfish” and “altruistic” predator characteristics are then shown to be necessary and sufficient for group selection predominance in this class of models. Maynard Smith's criterion M < 1 (Group selection, Quart. Rev. Biol., June 1976, pp. 277–283) is shown to be sufficient but not necessary for group selection predominance.     

Human dehydroepiandrosterone sulfotransferase pharmacogenetics: Quantitative Western analysis and gene sequence polymorphisms

Dehydroepiandrosterone sulfotransferase (DHEA ST) catalyzes the sulfation of DHEA and other hydroxysteroids. DHEA ST enzymatic activity in individual human liver biopsy samples has been shown to vary over a five-fold range, and frequency distribution histograms are bimodal, with approximately 25% of subjects included in a high activity subgroup. We set out to characterize the molecular basis for variation in human liver DHEA ST activity. The first step involved performing quantitative Western analysis of cytosol preparations from 92 human liver samples that had been phenotyped with regard to level of DHEA ST enzymatic activity. There was a highly significant correlation (r_s = 0.635, P < 0.0001) between levels of DHEA ST activity and immunoreactive protein. We next attempted to determine whether the expression of DHEA ST might be controlled, in part, by a genetic polymorphism. DNA was isolated from three “low” and three “high” DHEA ST activity liver samples. Exons and the 5′-flanking region of the DHEA ST gene (STD) were amplified for each of these samples with the polymerase chain reaction (PCR). When compared with “wild type” STD sequence, some of the samples contained a T → C transition at DHEA ST cDNA nucleotide 170, located within exon 2, resulting in a Met 57 → Thr change in amino acid. Other samples contained an A → T transversion at nucleotide 557 within STD exon 4 that resulted in a Glu 186 → Val change. STD exons 2 and 4 were then sequenced for DNA isolated from an additional 87 liver samples that had been phenotyped with regard to level of DHEA ST enzymatic activity. The allele frequency for the exon 2 polymorphism in these samples was 0.027, whereas that for the exon 4 polymorphism was 0.038, but neither polymorphism was systematically related to the level of enzyme activity in these samples. Transient expression in COS-1 cells of cDNA that contained the nucleotide 170 and 557 polymorphisms, either separately or together, resulted in decreased expression of both DHEA ST enzymatic activity and level of immunoreactive protein, but only when the nucleotide 557 variant was present. Identification of common genetic polymorphisms within STD will now make it possible to test the hypothesis that those polymorphisms might alter in vivo expression and/or function of this important human steroid-metabolizing enzyme.     

Cell locomotion, nerve elongation, and microfilaments

A basic difference in locomotion between migratory cells and nerves correlates with a difference in distribution of certain microfilament systems. Lattice filaments are present where extension and movement of cell surface occur in both cell types. Bundles of sheath filaments which bind heavy meromyosin, are present in migratory cells, where displacement of the cell soma over the substratum occurs, but absent from nerves, where the cell body and axon remain fixed upon the substratum and “locomotion” is restricted to the axonal tip. It is proposed that the microfilament lattice is involved in the extension phase of locomotion, and the microfilament sheath in the contractile phase.     

Neurons as sensors: individual and cascaded chemical sensing

A single neuron sensor has been developed based on the interaction of gradient electric fields and the cell membrane. Single neurons are rapidly positioned over individual microelectrodes using positive dielectrophoretic traps. This enables the continuous extracellular electrophysiological measurements from individual neurons. The sensor developed using this technique provides the first experimental method for determining single cell sensitivity; the speed of response and the associated physiological changes to a broad spectrum of chemical agents. Binding of specific chemical agents to a specific combination of receptors induces changes to the extracellular membrane potential of a single neuron, which can be translated into unique “signature patterns” (SP), which function as identification tags. Signature patterns are derived using Fast Fourier Transformation (FFT) analysis and Wavelet Transformation (WT) analysis of the modified extracellular action potential. The validity and the sensitivity of the system are demonstrated for a variety of chemical agents ranging from behavior altering chemicals (ethanol), environmentally hazardous agents (hydrogen peroxide, EDTA) to physiologically harmful agents (pyrethroids) at pico- and femto-molar concentrations. The ability of a single neuron to selectively identify specific chemical agents when injected in a serial manner is demonstrated in “cascaded sensing”.     

Cellular aging studied by the reconstruction of replicating cells from nuclei and cytoplasms isolated from normal human diploid cells

Cytochalasin B (CB) was used to enucleate cells (cytoplasts) and to obtain karyoplasts (nuclei) from the human diploid fetal lung fibroblast strain WI-38. Fusion of cytoplasts and nuclei from young and old cells was accomplished with the aid of inactivated Sendai virus. Viable nuclei may be obtained from the karyoplast pellet after passage through a layer of bovine albumin which retains any contamination cytoplasts. The majority of successful fusions forming “whole cells” occurred when cytoplast from “old” cultures (PDL 40–51) and karyoplasts from “young” cultures were used (PDL 12–22), but almost always resulted in limited division of the viable reconstructed cells. When successful fusion occurred between “young” cytoplasts and “young” karyoplasts the number of cell divisions obtained was comparable to control cells kept under similar conditions.     

Adult neurogenesis and neuronal regeneration in the brain of teleost fish

Whereas adult neurogenesis appears to be a universal phenomenon in the vertebrate brain, enormous differences exist in neurogenic potential between “lower” and “higher” vertebrates. Studies in the gymnotiform fish Apteronotus leptorhynchus and in zebrafish have indicated that the relative number of new cells, as well as the number of neurogenic sites, are at least one, if not two, orders of magnitude larger in teleosts than in mammals. In teleosts, these neurogenic sites include brain regions homologous to the mammalian hippocampus and olfactory bulb, both of which have consistently exhibited neurogenesis in all species examined thus far. The source of the new cells in the teleostean brain are intrinsic stem cells that give rise to both glial cells and neurons. In several brain regions, the young cells migrate, guided by radial glial fibers, to specific target areas where they integrate into existing neural networks. Approximately half of the new cells survive for the rest of the fish’s life, whereas the other half are eliminated through apoptotic cell death. A potential mechanism regulating development of the new cells is provided by somatic genomic alterations. The generation of new cells, together with elimination of damaged cells through apoptosis, also enables teleost fish rapid and efficient neuronal regeneration after brain injuries. Proteome analysis has identified a number of proteins potentially involved in the individual regenerative processes. Comparative analysis has suggested that differences between teleosts and mammals in the growth of muscles and sensory organs are key to explain the differences in adult neurogenesis that evolved during phylogenetic development of the two taxa.     

Improved Kupffer's Gold Chloride Method for Demonstrating the Stellate Cells Storing Retinol (Vitamin A) in the Liver and Extrahepatic Organs of Vertebrates

This paper describes our modification of the classical gold chloride technique for the demonstration of the perisinusoidal stellate cells in the liver. The results of the method as introduced by von Kupffer (1876) are unpredictable. Using our modification, high quality gold preparations can be obtained. The method allows selective staining of retinol (vitamin A)-storing stellate cells in the liver and extrahepatic organs of various vertebrates. The sensitivity of the reaction is comparable to that of the fluorescence method for retinol. The technique is simple and the preparations keep for several years. Formol fixed specimens can be counterstained with Sudan III or hematoxylin. We have also developed a simple technique for making “sinusoid-net preparations,” removing the parenchymal cells by supersonication. The clear visualization of the stellate cells that results has made it possible to study the distribution of these cells.     

Fusion with enucleated fibroblasts corrects “I-cell” defect

Fusions have been carried out between fibroblasts from patients with “I-cell” disease and enucleated human fibroblasts with a single lysosomal enzyme deficiency derived from patients with G_M1-gangliosidosis, Sandhoff disease and mannosidosis. Pure cytoplasts were obtained using cytochalasin B treatment followed by fluorescence activated cell sorting. After fusion with whole “I-cells”, the cybrid populations showed a restoration of deficient lysosomal enzyme activity and also the abnormal electrophoretic pattern characteristic for the residual hexosaminidase activity in “I-cells” was found to be corrected. The results described in this paper indicate that the defective post-translational modification, which is responsible for the multiple lysosomal enzyme deficiency, can be corrected by a factor that is stable for at least three days in enucleated cells. During this period the cytoplasmic factor can act without the need of de novo synthesis but the absence of correction in in vitro experiments shows that cellular integrity is required.