Human polymorphonuclear neutrophil (PMN) responses to G protein-coupled chemoattractants are highly dependent upon store-operated Ca2+ entry (SOCE). Recent research suggests that SOCE currents can be mediated by a variety of related channel proteins of the transient receptor potential superfamily. SOCE has been regarded as a specific response to depletion of cell calcium stores. We hypothesized that net SOCE might reflect the contributions of more than one calcium entry pathway. SOCE was studied in normal human PMN using Ca2+ and Sr2+ ions. We found that PMN SOCE depends on at least two divalent cation influx pathways. One of these was nonspecific and Sr2+ permeable; the other was Ca2+ specific. The two pathways show different degrees of dependence on store depletion by thapsigargin and ionomycin, and differential sensitivity to inhibition by 2-aminoethyoxydiphenyl borane and gadolinium. The inflammatory G protein-coupled chemoattractants fMLP, platelet-activating factor, and IL-8 elicit unique patterns of Sr2+ and Ca2+ influx channel activation, and SOCE responses to these agonists displayed differing degrees of linkage to prior Ca2+ store depletion. The mechanisms of PMN SOCE responses to G protein-coupled chemoattractants are physiologically diverse. They appear to reflect Ca2+ transport through a variety of channels that are independently regulated to varying degrees by store depletion and by G protein-coupled receptor activation.
The activity of PMN CXCR2 receptors soon after injury may be reflected in the later clinical sequelae of PMN activity. High CXCR2 activity may correlate with PMN hyperfunction and outcomes such as ARDS, whereas the loss of CXCR2 function in inflammatory environments may impair PMN functions in a manner that predisposes to pneumonia or sepsis. Early responses of PMN CXC receptors to injury may influence the clinical course of trauma patients.
Poly(3-octylthiophene)/silver nanocomposites (P3OT/Ag) were prepared by impregnating the polymer powder
in silver perchlorate salt solutions. The total silver content, up to 6 wt %, was determined by inductively
coupled plasma atomic absorption spectroscopy (ICP-AAS). The electric conductivities of the composites
were measured and correlated with the silver content. Conductivity increased by more than 5 orders of
magnitude with silver doping. The incorporated silver was speciated by X-ray diffraction (XRD). Silver was
found in the form of both Ag and AgCl, predominantly in metallic nanocrystallites. The size distribution of
the nanoparticles, determined from transmission electron microscopy (TEM), was found to be bimodal with
two maxima around 3 and 17 nm, correlating with the two forms of silver in the composite. Increased
conductivity was interpreted by results obtained by photoacoustic Fourier transform infrared spectroscopy
(PAS-FTIR). The observed large Seebeck coefficient of P3OT is promising from the point of view of
thermoelectric application.
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