Clonal distribution of bone sialoprotein-binding protein gene among Staphylococcus aureus isolates associated with bloodstream infections

Staphylococcus aureus is a leading cause of bloodstream infections (BSI) and diseases that may be caused by hematogenous spread. The staphylococcal adhesin, for which the association with the infections emerging as a complication of septicemia has been well documented, is a bone sialoprotein-binding protein (Bbp). The aim of the study was to assess the prevalence of a bbp gene in S. aureus bloodstream isolates associated with BSI and to investigate to what degree the distribution of this gene is linked to the clonality of the population. Spa typing, used in order to explore the genetic population structure of the isolates, yielded 29 types. Six spa clusters and seven singletons were identified. The most frequent was spa clonal complex CC021 associated with MLST CC30 (38 %). The bbp gene was found in 47 % of isolates. Almost all isolates (95 %) clustered in spa clonal complex CC021 were positive for this gene. All isolates carrying the bbp gene were sensitive to methicillin, and if clustered in the spa CC021, belonged to agr group III. Our study shows that Bbp is not strictly associated with BSI. However, one may conclude that for clonally related S. aureus strains most commonly causing BSI, the risk of Bbp-mediated complications of septicemia is expected to be higher than for other strains.     

Diamide amino-imidazoles: a novel series of γ-secretase inhibitors for the treatment of Alzheimer's disease

The synthesis and structure-activity relationship (SAR) of a novel series of di-substituted imidazoles, derived from modification of DAPT, are described. Subsequent optimization led to identification of a highly potent series of inhibitors that contain a β-amine in the imidazole side-chain resulting in a robust in vivo reduction of plasma and brain Aβ in guinea pigs. The therapeutic index between Aβ reductions and changes in B-cell populations were studied for compound 10h.     

Effect of Chromosome Tethering on Nuclear Organization in Yeast

Interphase chromosomes in Saccharomyces cerevisiae are tethered to the nuclear envelope at their telomeres and to the spindle pole body (SPB) at their centromeres. Using a polymer model of yeast chromosomes that includes these interactions, we show theoretically that telomere attachment to the nuclear envelope is a major determinant of gene positioning within the nucleus only for genes within 10 kb of the telomeres. We test this prediction by measuring the distance between the SPB and the silent mating locus (HML) on chromosome III in wild–type and mutant yeast strains that contain altered chromosome-tethering interactions. In wild-type yeast cells we find that disruption of the telomere tether does not dramatically change the position of HML with respect to the SPB, in agreement with theoretical predictions. Alternatively, using a mutant strain with a synthetic tether that localizes an HML-proximal site to the nuclear envelope, we find a significant change in the SPB-HML distance, again as predicted by theory. Our study quantifies the importance of tethering at telomeres on the organization of interphase chromosomes in yeast, which has been shown to play a significant role in determining chromosome function such as gene expression and recombination.     

Bacterioplankton nutrient metabolism in the Eastern Tropical North Pacific

Bacterioplankton nutrient metabolism in the Eastern Tropical North Pacific (ETNP) was assessed using specific activities of intracellular nitrogen (N) assimilation enzymes and hydrolytic ectoenzymes during amendment experiments, mesocosms, and diel studies of in situ rates. Glutamine synthetase (GS) and assimilatory nitrate reductase (ANR) were used to investigate N bioavailability, alkaline phosphatase (AP) to assess phosphorous (P) bioavailability and β-glucosidase (β-Glu) to detect shifts in the use of labile dissolved organic carbon (DOC). Conditions regulating activity of each enzyme were tested using incubations of < 0.6 mm size-fractionated seawater amended with different combinations of N, P, and DOC as glucose. Overall, N-deficiency was indicated by pronounced growth stimulation and repression of GS and ANR activity in incubations amended with dissolved free amino acid and ammonium. Phosphate and glucose amendments produced little or no growth stimulation, but did influence activity of all enzymes measured. Enzyme activities of bacterioplankton in mesocosms of whole plankton indicated enhanced N-deficiency and glucoside hydrolysis when the plankton community was released from any P-deficiency. Spatially, enzyme activity of bacterioplankton during two diel studies (at one slope and one open-ocean station) suggested greater N-deficiency at surface depths than within the chlorophyll maximum where activity of AP and b-Glu was often greatest. There was also greater GS and ANR activity at the open-ocean station, which had lower concentrations of dissolved inorganic N (DIN) relative to soluble reactive P (SRP), than along the continental slope of Mexico. These data suggest that bacterioplankton in surface waters of the ETNP require a large flux of DOC to drive N-deficiency; whereas, bacterioplankton deeper in the chlorophyll maximum depend on hydrolysis of complex DOC and DOP to meet their carbon demand in the presence of elevated nutrients with a low DIN:SRP ratio.     

Amount of Colicin Release in Escherichia coli Is Regulated by Lysis Gene Expression of the Colicin E2 Operon

The production of bacteriocins in response to worsening environmental conditions is one means of bacteria to outcompete other microorganisms. Colicins, one class of bacteriocins in Escherichia coli, are effective against closely related Enterobacteriaceae. Current research focuses on production, release and uptake of these toxins by bacteria. However, little is known about the quantitative aspects of these dynamic processes. Here, we quantitatively study expression dynamics of the Colicin E2 operon in E. coli on a single cell level using fluorescence time-lapse microscopy. DNA damage, triggering SOS response leads to the heterogeneous expression of this operon including the cea gene encoding the toxin, Colicin E2, and the cel gene coding for the induction of cell lysis and subsequent colicin release. Advancing previous whole population investigations, our time-lapse experiments reveal that at low exogenous stress levels all cells eventually respond after a given time (heterogeneous timing). This heterogeneous timing is lost at high stress levels, at which a synchronized stress response of all cells 60 min after induction via stress can be observed. We further demonstrate, that the amount of colicin released is dependent on cel (lysis) gene expression, independent of the applied exogenous stress level. A heterogeneous response in combination with heterogeneous timing can be biologically significant. It might enable a bacterial population to endure low stress levels, while at high stress levels an immediate and synchronized population wide response can give single surviving cells of the own species the chance to take over the bacterial community after the stress has ceased.     

In vivo measure of average bacterial cell size from a polarized light scattering function.

A particular combination of elements of the Mueller matrix for scattering of polarized light given by (S34 + S14)/(S11 + S13) identical to (S34/S11)++ is measured vs angle at a wavelength of 633 nm for randomly oriented suspensions of several species of bacteria in different stages of growth. (This combination of elements is dominated in the present measurements by the behavior of the normalized S34 matrix element, as is indicated by the notation defined on the right side of the equation.) The resulting graph in each case shows an oscillating function of angle. This function is compressed toward smaller angles when the bacteria are in the exponential phase of growth in comparison with results for a suspension of the same bacteria in the stationary (starving-smaller cells) phase of growth. Microscopic measurements were made to determine, for each case, the average dimensions of the bacterial population. Graphs were then plotted of the peak positions from the Mueller matrix function plots vs either cell length or cell diameter. The function was shown to be strongly correlated with cell diameter under the conditions of this experiment and poorly correlated with cell length. The measurements were shown to have a sensitivity to changes in average diameter of about 20 nm.