Modeling and investigation of neural activity in the thalamus

Although it is known that electroencephalographic (EEG) spindle oscillations are generated and maintained in the thalamus, the underlying mechanisms are still not clear. In this paper, a physiologically based continuum model is used to explore the role of the thalamus in generation of EEG rhythms, particularly spindle oscillations. Furthermore, local interneurons (LIs) which were not previously included in such modeling are studied. A previous continuum model is extended to incorporate LIs within relay nuclei and self-connections of the reticular (RE) nucleus into investigation of the roles and functions of groups of thalamic neurons. The isolated thalamus is analysed into five distinct classes of substructures. Analysis of the properties of waves generated, leads to the main results that: (1) an isolated RE nucleus cannot generate spindle oscillations, but it is essential to generation of spindle oscillations in cooperation with the relay cells; (2) the LIs can also generate spindle oscillations in conjunction with the relay cells; (3) the self-connection loop within the LI population and the one within the RE nucleus both make spindle oscillations easier to produce than in the absence of these connections; (4) the LIs have similar effects to the RE nucleus, except that they are purely inhibitory, whereas the latter has both direct inhibitory effects on relay cells, and indirect net excitatory effects by inhibiting LIs which inhibit relay cells, and (6) self-connections amongst the LIs have equivalent effects to self-connections within the RE nucleus.     

Value of models for membrane budding

The budding of membranes and curvature generation is common to many forms of trafficking in cells. Clathrin-mediated endocytosis, as a prototypical example of trafficking, has been studied in great detail using a variety of experimental systems and methods. Recently, advances in experimental methods have led to great strides in insights on the molecular mechanisms and the spatiotemporal dynamics of the protein machinery associated with membrane curvature generation. These advances have been ably supported by computational models, which have given us insights into the underlying mechanical principles of clathrin-mediated endocytosis. On the other hand, targeted experimental perturbation of membranes has lagged behind that of proteins in cells. In this area, modeling is especially critical to interpret experimental measurements in a mechanistic context. Here, we discuss the contributions made by these models to our understanding of endocytosis and identify opportunities to strengthen the connections between models and experiments.     

Analyzing Craniofacial Morphogenesis in Zebrafish Using 4D Confocal Microscopy

Time-lapse imaging is a technique that allows for the direct observation of the process of morphogenesis, or the generation of shape. Due to their optical clarity and amenability to genetic manipulation, the zebrafish embryo has become a popular model organism with which to perform time-lapse analysis of morphogenesis in living embryos. Confocal imaging of a live zebrafish embryo requires that a tissue of interest is persistently labeled with a fluorescent marker, such as a transgene or injected dye. The process demands that the embryo is anesthetized and held in place in such a way that healthy development proceeds normally. Parameters for imaging must be set to account for three-dimensional growth and to balance the demands of resolving individual cells while getting quick snapshots of development. Our results demonstrate the ability to perform long-term in vivo imaging of fluorescence-labeled zebrafish embryos and to detect varied tissue behaviors in the cranial neural crest that cause craniofacial abnormalities. Developmental delays caused by anesthesia and mounting are minimal, and embryos are unharmed by the process. Time-lapse imaged embryos can be returned to liquid medium and subsequently imaged or fixed at later points in development. With an increasing abundance of transgenic zebrafish lines and well-characterized fate mapping and transplantation techniques, imaging any desired tissue is possible. As such, time-lapse in vivo imaging combines powerfully with zebrafish genetic methods, including analyses of mutant and microinjected embryos.     

Expression of starvation-induced genes in zygotes ofDictyostelium discoideum

Two cDNA fragments induced in developing zygotes ofDictyostelium discoideum were isolated by mRNA differential display. the relevant genes were also found to be expressed during asexual development, suggesting that sexual and asexual development share common molecular mechanisms inD. discoideum.     

Plasmid instability in an industrial strain ofBacillus subtilis grown in chemostat culture

Summary A pUB110-derived plasmid/Bacillus subtilis host combination was segregationally unstable when grown in chemostat culture with complex or minimal medium and under starch, glucose or magnesium limitation. The kinetics of plasmid loss were described in terms of the difference in growth rates between plasmid-containing and plasmid-free cells (d) and the rate at which plasmid-free cells were generated from plasmid-containing cells (R). Loss of plasmid-containing cells from the population was d dominated. Changes in medium composition and the nature of growth limitation caused variations in both d and R. The plasmid was most stable in glucose-limited chemostat cultures with minimal medium and least stable under starch limitation with complex complex medium. R and d were smaller for cultures in complex media than those in minimal media. Limitation by starch induced expression of the plasmid-encoded HT amylase gene and was associated with increased values of R and d. Magnesium limitation in minimal medium caused a significant increase in d and a decrease in R.Abbreviations Cm chloramphenicol - Kan kanamycin - Cm^r cells resistant to chloramphenicol (5 mg L^–1) - Kan^r cells resistant to kanamycin (5 mg L^–1) - Cm^sKan^s cells sensitive to chloramphenicol and kanamycin