Mycoplasma pneumoniae induces airway epithelial cell expression of MUC5AC in asthma.

As excess mucin expression can contribute to the exacerbation of asthma, the present authors hypothesised that Mycoplasma pneumoniae significantly induces MUC5AC (the major airway mucin) expression in airway epithelial cells isolated directly from asthmatic subjects. A total of 11 subjects with asthma and six normal controls underwent bronchoscopy with airway brushing. Epithelial cells were cultured at an air-liquid interface and incubated with and without M. pneumoniae for 48 h, and in the presence and absence of nuclear factor (NF)-kappaB and a toll-like receptor (TLR)2 inhibitor. Quantitative PCR was performed for MUC5AC and TLR2 mRNA. MUC5AC protein and total protein were determined by ELISA. M. pneumoniae exposure significantly increased MUC5AC mRNA and protein expression after 48 h in epithelial cells isolated from asthmatic, but not from normal control subjects, at all concentrations as compared to unexposed cells. TLR2 mRNA expression was significantly increased in asthmatic epithelial cells at 4 h compared with unexposed cells. NF-kappaB and TLR2 inhibition reduced MUC5AC expression to the level of the unexposed control in both groups. Mycoplasma pneumoniae exposure significantly increased MUC5AC mRNA and protein expression preferentially in airway epithelial cells isolated from asthmatic subjects. The toll-like receptor 2 pathway may be involved in this process.

C-Terminal alternative splicing changes the gating properties of a human spinal cord calcium channel alpha 1A subunit.

The calcium channel alpha(1A) subunit gene codes for proteins with diverse structure and function. This diversity may be important for fine tuning neurotransmitter release at central and peripheral synapses. The alpha(1A) C terminus, which serves a critical role in processing information from intracellular signaling molecules, is capable of undergoing extensive alternative splicing. The purpose of this study was to determine the extent to which C-terminal alternative splicing affects some of the fundamental biophysical properties of alpha(1A) subunits. Specifically, the biophysical properties of two alternatively spliced alpha(1A) subunits were compared. One variant was identical to an isoform identified previously in human brain, and the other was a novel isoform isolated from human spinal cord. The variants differed by two amino acids (NP) in the extracellular linker between transmembrane segments IVS3 and IVS4 and in two C-terminal regions encoded by exons 37 and 44. Expression in Xenopus oocytes demonstrated that the two variants were similar with respect to current-voltage relationships and the voltage dependence of steady-state activation and inactivation. However, the rates of activation, inactivation, deactivation, and recovery from inactivation were all significantly slower for the spinal cord variant. A chimeric strategy demonstrated that the inclusion of the sequence encoded by exon 44 specifically affects the rate of inactivation. These findings demonstrate that C-terminal structural changes alone can influence the way in which alpha(1A) subunits respond to a depolarizing stimulus and add to the developing picture of the C terminus as a critical domain in the regulation of Ca(2+) channel function.

Shear stress induces ATP-independent transient nitric oxide release from vascular endothelial cells, measured directly with a porphyrinic microsensor.

Shear stress causes the vascular endothelium to release nitric oxide (NO), which is an important regulator of vascular tone. However, direct measurement of NO release after the imposition of laminar flow has not been previously accomplished because of chemical (oxidative degradation) and physical (diffusion, convection, and washout) complications. Consequently, the mechanism, time course, kinetics, and Ca2+ dependence of NO release due to shear stress remain incompletely understood. In this study, we characterized these parameters by using fura 2 fluorescence and a polymeric porphyrin/Nafion-coated carbon fiber microsensor (detection limit, 5 nmol/L; response time, 1 millisecond) to directly measure changes in [Ca2+]i and NO release due to shear stress or agonist (ATP or brominated Ca2+ ionophore [Br-A23187]) from bovine aortic endothelial cells. The cells were grown to confluence on glass coverslips, loaded with fura 2-AM, and mounted in a parallel-plate flow chamber (volume, 25 microL). The microsensor was positioned approximately 100 microns above the cells with its long axis parallel to the direction of flow. Laminar flow of perfusate was maintained from 0.04 to 1.90 mL/min, which produced shear stresses of 0.2 to 10 dyne/cm2. Shear stress caused transient NO release 3 to 5 seconds after the initiation of flow and 1 to 3 seconds after the rise in [Ca2+]i, which reached a plateau after 35 to 70 seconds. Although the amount (peak rate) of NO release increased as a function of the shear stress (0.08 to 3.80 pmol/s), because of the concomitant increase in the flow rate, the peak NO concentration (133 +/- 9 nmol/L) remained constant. Maintenance of flow resulted in additional transient NO release, with peak-to-peak intervals of 15.5 +/- 2.5 minutes. During this 13- to 18-minute period, when the cells were unresponsive to shear stress, exogenous ATP (10 mumol/L) or Br-A23187 (10 mumol/L) evoked NO release. Prior incubation of the cells with exogenous NO or the removal and EGTA (100 mumol/L) chelation of extracellular Ca2+ blocked shear stress but not ATP-dependent NO release. The kinetics of shear stress-induced NO release (2.23 +/- 0.07 nmol/L per second) closely resembled the kinetics of Ca2+ flux but differed markedly from the kinetics of ATP-induced NO release (5.64 +/- 0.32 nmol/L per second). These data argue that shear stress causes a Ca(2+)-mediated ATP-independent transient release of NO, where the peak rate of release but not the peak concentration depends on the level of shear stress.(ABSTRACT TRUNCATED AT 400 WORDS)

A novel beta subunit increases rate of inactivation of specific voltage-gated potassium channel alpha subunits.

Voltage-gated potassium channel beta subunits are cytoplasmic proteins that co-purify with the pore-forming alpha subunits. One of these subunits, Kv beta 1 from rat brain, was previously demonstrated to increase the rate of inactivation of Kv1.1 and Kv1.4 when co-expressed in Xenopus oocytes. We have cloned and characterized a novel voltage-gated K+ channel beta subunit. The cDNA, designated Kv beta 3, has a 408-amino acid open reading frame. It possesses a unique 79-amino acid N-terminal leader, but is identical with rat Kv beta 1 over the 329 C-terminal amino acids. The Kv beta 3 transcript was found in many tissues, but was most abundant in aorta and left ventricle of the heart. Co-expression of Kv beta 3 with K+ channel alpha subunits shows that this beta subunit can increase the rate of inactivation from 4- to 7-fold in a Kv1.4 or Shaker B channel. Kv beta 3 had no effect on Kv1.1, unlike Kv beta 1 which can increase rate of inactivation of this alpha subunit more than 100-fold. Other kinetic parameters were unaffected. This study shows that voltage-gated K+ channel beta subunits are present outside the central nervous system, and that at least one member of this family selectively modulates inactivation of K+ channel alpha subunits.

Coordinate depression of bradykinin receptor recycling and microtubule-dependent transport by taxol.

Significant cardiovascular side effects have limited the use of taxol as an anticancer drug. A link between decreased plasma membrane dynamics and taxol has been implied because taxol can inhibit intracellular vesicle movements. Reduced membrane recycling caused by taxol could inhibit agonist-evoked Ca2+ signaling within endothelial cells, resulting in endothelium-dependent vasodilation. Bradykinin and ATP are two agonists that evoke Ca2+ transients in endothelial cells. Since the bradykinin receptor-agonist complex is internalized and recycled whereas the ATP agonist-receptor complex is not, we expected that a taxol inhibition of recycling would decrease bradykinin but not ATP receptor activity. We found that taxol depresses (i) the frequency (to 41% of control) and velocity (to 55% of control) of microtubule-dependent vesicle transport and (ii) bradykinin-evoked cytosolic Ca2+ transients (to 76% of control) in bovine aortic endothelial cells. In studying bradykinin receptor desensitization, which reflects receptor recycling, we demonstrate that taxol inhibits bradykinin-evoked Ca2+ transients by 50%. Taxol did not significantly alter ATP-evoked Ca2+ transients in either single-exposure or desensitization experiments. We suggest that taxol's reduction of bradykinin-evoked Ca2+ transients is due to altered microtubule-dependent membrane recycling. This report describes taxol's ability to alter plasma membrane composition through effects on vesicle transport and membrane trafficking pathways. This finding provides a possible mechanism by which taxol can substantially alter cardiovascular function.

Voltage and temperature dependence of single K+ channels isolated from canine cardiac sarcoplasmic reticulum.

The temperature and voltage dependence of gating and conductance of sarcoplasmic reticulum K+ channels (S-R K+) isolated from adult canine hearts were studied using the reconstituted bilayer technique. Fusion of vesicles from this preparation frequently resulted in the incorporation of a single channel. Only bilayers into which a single S-R K+ channel had fused were studied. The three conductance states of the channel, fully open (O2), substate conductance (O1), and closed (C) were studied as a function of voltage (-50 to +50 mV) and temperature (16 to 37 degrees C). Permeation through the O1 state showed the same temperature dependence as the O2 state corresponding to an enthalpy of permeation of 4.1-4.2 kcal/mol, which is similar to that for K+ diffusion through water. As expected, increased temperature increased the frequency of gating transitions and shortened the average dwell time spent in any conductance state. Over the range of 25 to 37 degrees C, the average dwell time spent in the O1, O2, and C states decreased by 44 +/- 11, 36 +/- 13, and 78 +/- 7% (n = 3 to 4 channels), respectively. The ratio of probabilities between the various conductance states was not strongly temperature sensitive. Analysis of the voltage dependence of this channel was carried out at 37 degrees C and revealed that the dwell times of the O1 and O2 states were voltage insensitive and the probability ratio (PO2:PO1) was approximately 7 and was voltage insensitive. Nonlinear least-squares analysis of dwell times revealed that the closed state was biexponential and was thus composed of a fast (Cf) and a slow (C8) component.Tcf was voltage insensitive with an average value of 5.9 ms, whereas tau c was approximately two orders of magnitude slower and was voltage dependent. The voltage dependence of Cs was described by Tau c (ms) = exp(-0.025-(Vm (mV) - 250)).