Multivariate analysis of Neisseria DNA restriction endonuclease patterns

Chromosomal DNA was extracted from eleven Neisseria meningitidis and seven Neisseria gonorrhoeae isolates and cleaved with the restriction enzyme HindIII. The DNA fragments were separated according to their size, using a 4% polyacrylamide gel. The band patterns obtained were digitized and statistically analysed by the SIMCA method. To develop the models for N. meningitidis (class 1) and N. gonorrhoeae (class 2), all eleven meningococci and seven gonococci, were used. All strains were classified correctly and showed an extremely good class separation.     

Real-time fluorimetric analysis of gramicidin D- and alamethicin-induced K+ efflux from Sf9 and Cf1 insect cells.

Gramicidin D and alamethicin are pore-forming peptides which exhibit lethal properties against a large spectrum of cells. Despite a wealth of experimental data from artificial membranes, the time course and quantitative analysis of the activity of these ionophores are not well described in living cells. In the present study, the newly described fluorescent dye CD-222 was used to monitor extracellular potassium ion concentration and report the effects of these antibiotics on the K+ permeability of the plasma membrane of Spodoptera frugiperda (Sf9) and Choristoneura fumiferana (Cf1) insect cells. Both peptides induced a rapid efflux of intracellular K+ as a consequence of ion channel formation in the cell membrane. K+ efflux began without any measurable delay. While the final extracellular K+ concentration was unaffected by ionophore concentration, the rate of K+ efflux was dose dependent. Using a model describing the partition of the peptides in lipid membranes, the K+ efflux kinetic parameters were determined for both cell types and both pore formers. The proposed stoichiometry for the channel formed by gramicidin in living cells is in good agreement with the two-monomers model based on data from artificial membrane systems. The K+-permeable channel formed by alamethicin in insect cells appears to involve three monomers.     

Host–microbial symbiosis in the mammalian intestine: exploring an internal ecosystem

The mammalian intestine contains a complex, dynamic, and spatially diversified society of nonpathogenic bacteria. Very little is known about the factors that help establish host-microbial symbiosis in this open ecosystem. By introducing single genetically manipulatable components of the microflora into germfree mice, simplified model systems have been created that will allow conversations between host and microbe to be heard and understood. Other paradigms of host–microbial symbiosis suggest that these interactions will involve an exchange of biochemical signals between host and symbionts as well as among the bacteria themselves. The integration of molecular microbiology, cell biology, and gnotobiology should provide new insights about how we adapt to a microbial world and reveal the roles played by our indigenous ‘nonpathogenic’ flora. BioEssays 20 :336-343, 1998. © 1998 John Wiley & Sons, Inc.     

Impaired Cx43 gap junction endocytosis causes morphological and functional defects in zebrafish

Gap junctions mediate direct cell-to-cell communication by forming channels that physically couple cells, thereby linking their cytoplasm, permitting the exchange of molecules, ions, and electrical impulses. Gap junctions are assembled from connexin (Cx) proteins, with connexin 43 (Cx43) being the most ubiquitously expressed and best studied. While the molecular events that dictate the Cx43 life cycle have largely been characterized, the unusually short half-life of Cxs of only 1–5 h, resulting in constant endocytosis and biosynthetic replacement of gap junction channels, has remained puzzling. The Cx43 C-terminal (CT) domain serves as the regulatory hub of the protein affecting all aspects of gap junction function. Here, deletion within the Cx43 CT (amino acids 256–289), a region known to encode key residues regulating gap junction turnover, is employed to examine the effects of dysregulated Cx43 gap junction endocytosis using cultured cells (Cx43^∆256-289) and a zebrafish model (cx43^lh10). We report that this CT deletion causes defective gap junction endocytosis as well as increased gap junction intercellular communication. Increased Cx43 protein content in cx43^lh10 zebrafish, specifically in the cardiac tissue, larger gap junction plaques, and longer Cx43 protein half-lives coincide with severely impaired development. Our findings demonstrate for the first time that continuous Cx43 gap junction endocytosis is an essential aspect of gap junction function and, when impaired, gives rise to significant physiological problems as revealed here for cardiovascular development and function.     

Mikroben unter Strom

Microbes wired up – From wastewater treatment to bioelectrotechnology Electron conducting microbes – this still sounds like science fiction or at least like an exotic natural phenomenon. Groundbreaking research in this area, however, indicates that this process seems to be widely spread within anaerobic microbial ecology. Microbes “wire up” with their living and non‐living surrounding to construct energetic networks. With microbial bioelectrochemical systems, we try to utilize this knowledge for environmental and biotechnological applications. While initially, the recovery of energy as electric current in microbial fuel cells was the main R&D target, our new scientific insights of microbial extracellular electron transfer allow us to make controlled use of this phenomenon for a multitude of further applications.     

Characterization of a new myrosinase in Brassica napus

A full-length cDNA clone defining the new myrosinase gene family MC in Brassica napus was isolated and sequenced. Southern hybridization showed that the MC family probably consists of 3 or 4 genes in B. napus. MC genes are expressed in the developing seed, but not in the vegetative tissues investigated. In situ hybridizations to developing seeds showed that the MC genes are expressed in the myrosin cells of the embryo axis and the cotyledons. Complexes with myrosinase and myrosinase-binding protein (MBP) were purified and characterized. Sequencing of peptides from myrosinases occurring in the complexes showed that the 70 kDa myrosinase is encoded by the MC genes, whereas the 65 kDa myrosinase is encoded by the MB genes. This is in contrast to the 75 kDa myrosinase which occurs in free form and is encoded by the MA genes. Deglycosylations of the myrosinase complexes and the free myrosinase showed that the molecular sizes of the myrosinases could be reduced significantly by this treatment, and that the size differences between the different myrosinases are mainly due to differences in glycosylation.     

Influence of inoculum morphology on growth of Atropa belladonna hairy roots and production of tropane alkaloids

Summary The specific growth rate of Atropa belladonna hairy roots measured in terms of root length increased by about 25% to 0.49 d^-1 when the inoculum consisted of a root with the primary root tip excised. The biomass dry weight produced after 14 d increased by 28%. In contrast, presence of laterals in the inoculum with or without lateral tips excised did not influence the growth rate. Although hyoscyamine was found to accumulate at higher concentrations in the more mature root tissues (2.1 ± 0.2 mg g^-1) than in the tips (1.1 ± 0.3 mg g^-1), hyoscyamine content in the harvested roots was independent of inoculum morphology.     

A bacteria-induced switch of sympathetic effector mechanisms augments local inhibition of TNF-alpha and IL-6 secretion in the spleen.

It is believed that an inflammation-induced activation of the CNS leads to an inhibition of overshooting immune responses to prevent extensive local cytokine secretion. However, immunosuppression by the sympathetic nervous system may be unfavorable when bacteria are present locally and when TNF-alpha is necessary to overcome infection. We now report in a superfusion model, using mouse spleen slices, that although local Pseudomonas aeruginosa increased splenic TNF-alpha and IL-6 secretion severalfold over basal levels, electrically released neurotransmitters attenuated cytokine secretion to similar basal level as under bacteria-free conditions. Bacteria reversed noradrenergic inhibitory effector mechanisms: Under bacteria-free conditions, TNF-alpha secretion was very low and IL-6 secretion was mainly inhibited by alpha2-adrenoreceptor ligation. In the presence of bacteria, TNF-alpha and IL-6 secretion were high and IL-6 secretion was mainly inhibited by beta-adrenoreceptor ligation. The alpha- to beta-adrenoswitch of IL-6 inhibition in the presence of bacteria was mediated by the prior adrenergic regulation of TNF-alpha. In vivo, chemical abrogation of sympathetic inhibition reduced accumulation of bacteria in the spleen, which depended at least in part on TNF-alpha. This suggests that activation of the sympathetic nervous system may be a forerunner for accumulation of bacteria in tissue and consecutively sepsis due to intensified inhibition of TNF-alpha secretion.