Paraquat induced thiol modulation of Histoplasma capsulatum morphogenesis

Cysteine metabolism with the subsequent release of anionic thiols has been shown to be involved in yeast cell morphogenesis of the dimorphic, pathogenic fungus Histoplasma capsulatum. Following transfer to fresh medium, intracellular thiol levels during the initial 2–4 h appear to determine the eventual growth form. Mild oxidative stress induced by paraquat (methyl viologen) caused enhanced intracellular and extracellular thiol production and an increase in protein thiol formation. Mildly stressed cells continued to grow in the yeast form. Severe oxidative stress induced by high concentrations of paraquat resulted in lowered thiol production as well as reversion to the alternate mycelial morphology. These results suggest that thiol modulation of intracellular protein status may be involved in morphogenesis of H. capsulatum.     

Temperature coupling of mate attraction signals and female mate preferences in four populations of Enchenopa treehopper (Hemiptera: Membracidae)

Variation in temperature can affect the expression of a variety of important fitness‐related behaviours, including those involved with mate attraction and selection, with consequences for the coordination of mating across variable environments. We examined how temperature influences the expression of male mating signals and female mate preferences—as well as the relationship between how male signals and female mate preferences change across temperatures (signal–preference temperature coupling)—in Enchenopa binotata treehoppers. These small plant‐feeding insects communicate using plantborne vibrations, and our field surveys indicate they experience significant natural variation in temperature during the mating season. We tested for signal–preference temperature coupling in four populations of E. binotata by manipulating temperature in a controlled laboratory environment. We measured the frequency of male signals—the trait for which females show strongest preference—and female peak preference—the signal frequency most preferred by females—across a range of biologically relevant temperatures (18°C–36°C). We found a strong effect of temperature on both male signals and female preferences, which generated signal–preference temperature coupling within each population. Even in a population in which male signals mismatched female preferences, the temperature coupling reinforces predicted directional selection across all temperatures. Additionally, we found similar thermal sensitivity in signals and preferences across populations even though populations varied in the mean frequency of male signals and female peak preference. Together, these results suggest that temperature variation should not affect the action of sexual selection via female choice, but rather should reinforce stabilizing selection in populations with signal–preference matches, and directional selection in those with signal–preference mismatches. Finally, we do not predict that thermal variation will disrupt the coordination of mating in this species by generating signal–preference mismatches at thermal extremes.     

Cubic Membrane Structure in Amoeba (Chaos carolinensis) Mitochondria Determined by Electron Microscopic Tomography

Cubic membranes occur in a variety of membrane-bound organelles in many cell types. By transmission electron microscopy (TEM) these membrane systems appear to consist of highly curved periodic surfaces that fit mathematical models analogous to those used to describe lipidic cubic phases. For the first time, a naturally occurring cubic membrane system has been reconstructed in three dimensions by electron microscopic tomography, and its periodicity directly characterized. Double-tilt tomographic reconstruction of mitochondria in the amoeba, Chaos carolinensis, confirms that their cristae (inner membrane infoldings) have the cubic structure suggested by modeling studies based on thin-section TEM images. Analysis of the membrane surfaces in the reconstruction reveals the connectivity of the internal compartments within the mitochondria. In the cubic regions, the matrix is highly condensed and confined to a continuous, small space between adjacent cristal membranes. The cristae form large, undulating cisternae that communicate with the peripheral (inner membrane) compartment through narrow tubular segments as seen in other types of mitochondria. The cubic periodicity of these mitochondrial membranes provides an ideal specimen for measuring geometrical distortions in biological electron tomography. It may also prove to be a useful model system for studies of the correlation of cristae–matrix organization with mitochondrial activity.     

A molecular dynamics simulation of the structure and properties of a self assembled monolayer formed from an amphiphilic polymer on a water surface

The polymer poly (3-octyl-3′-oxanoyl thiophene) has alternating hydrophobic octyl and hydrophilic oxanoyl side chains in the “3” positions of the thiophene rings, rendering it an interesting amphiphilic electro-active material. The application of compression on the amphiphilic polymer (which forms self-assembled monolayers (SAMs) on a water surface) is investigated by molecular dynamics (MDs). It is found that there is a range of surface pressures in which the material possesses lattice order. As the compression is increased beyond a critical value breakdown occurs leading to the rupture of the surface layer. The results of the dynamics are interpreted via atomic plots, atom-pair radial distribution functions (RDF), torsional distribution functions and by monitoring some of the dihedral angles as functions of time.     

Investigation of the Physicochemical and Physicomechanical Properties of a Novel Intravaginal Bioadhesive Polymeric Device in the Pig Model

The purpose of this study was to develop and evaluate the bioadhesivity, in vitro drug release, and permeation of an intravaginal bioadhesive polymeric device (IBPD) loaded with 3′-azido-3′-deoxythymidine (AZT) and polystyrene sulfonate (PSS). Modified polyamide 6,10, poly(lactic-coglycolic acid), polyacrylic acid, polyvinyl alcohol, and ethylcellulose were blended with model drugs AZT and PSS as well as radio-opaque barium sulfate (BaSO4) and then compressed into caplet devices on a tableting press. One set of devices was coated with 2% w/v pentaerythritol polyacrylic acid (APE-PAA) while another remained uncoated. Thermal analysis was performed on the constituent polymers as well the IBPD. The changes in micro-environmental pH within the simulated human vaginal fluid due to the presence of the IBPD were assessed over a period of 30 days. Textural profile analysis indicated that the bioadhesivity of the APE-PAA-coated devices (3.699 ± 0.464 N; 0.0098 ± 0.0004 J) was higher than that of the uncoated devices (1.198 ± 0.150 N; 0.0019 ± 0.0001 J). In addition, BaSO4-facilitated X-ray imaging revealed that the IBPD adhered to pig vaginal tissue over the experimental period of 30 days. Controlled drug release kinetics was obtained over 72 days. During a 24-h permeation study, an increase in drug flux for both AZT (0.84 mg cm⁻² h⁻¹) and PSS (0.72 mg cm⁻² h⁻¹) was realized up to 12 h and thereafter a steady-state was achieved. The diffusion and dissolution dynamics were mechanistically deduced based on a chemometric and molecular structure modeling approach. Overall, results suggested that the IBPD may be sufficiently bioadhesive with desirable physicochemical and physicomechanical stability for use as a prolonged intravaginal drug delivery device.     

In vitro effects of tetraiodothyroacetic acid combined with X-irradiation on basal cell carcinoma cells

We investigated radiosensitization in an untreated basal cell carcinoma (TE.354.T) cell line and post-pretreatment with tetraiodothyroacetic acid (tetrac) X 1 h at 37°C, 0.2 and 2.0 µM tetrac. Radioresistant TE.354.T cells were grown in modified medium containing fibroblast growth factor-2, stem cell factor-1 and a reduced calcium level. We also added reproductively inactivated (30 Gy) “feeder cells” to the medium. The in vitro doubling time was 34.1 h, and the colony forming efficiency was 5.09 percent. These results were therefore suitable for clonogenic radiation survival assessment. The 250 kVp X-ray survival curve of control TE.354.T cells showed linear-quadratic survival parameters of α_X-ray = 0.201 Gy^?1 and β_X-ray = 0.125 Gy^?2. Tetrac concentrations of either 0.2 or 2.0 µM produced α_X-ray and β_X-ray parameters of 2.010 and 0.282 Gy^?1 and 2.050 and 0.837 Gy^?2, respectively. The surviving fraction at 2 Gy (SF₂) for control cells was 0.581, while values for 0.2 and 2.0 µM tetrac were 0.281 and 0.024. The SF₂ data show that tetrac concentrations of 0.2 and 2.0 µM sensitize otherwise radioresistant TE.354.T cells by factors of 2.1 and 24.0, respectively. Thus, radioresistant basal cell carcinoma cells may be radiosensitized pharmacologically by exposure to tetrac.