Restoration of the normal Clara cell phenotype after chronic allergic inflammation.

Bronchiolar Clara cells play a critical role in lung homoeostasis. The main goal of this study was to evaluate the effects of chronic allergy on these cells and the efficacy of budesonide (BUD) and montelukast (MK) in restoring their typical phenotypes after ovalbumin-induced chronic allergy in mice. Chronic allergy induced extensive bronchiolar Alcian blue-periodic acid-Schiff (AB/PAS)-positive metaplasia. In addition, cells accumulated numerous big electron-lucent granules negative for Clara cell main secretory protein (CC16), and consequently, CC16 was significantly reduced in bronchoalveolar lavage. A concomitant reduction in SP-D and CYP2E1 content was observed. The phenotypic changes induced by allergy were pharmacologically reversed by both treatments; MK was more efficient than BUD in doing so. MK decreased AB/PAS reactivity to control levels whereas they remained persistently elevated after BUD. Moreover, most non-ciliated cells recovered their normal morphology after MK, whereas for BUD normal cells coexisted with 'transitional' cells that contained remnant mucous granules and stained strongly for CC16 and SP-D. Glucocorticoids were also less able to reduce inflammatory infiltration and maintained higher percentage of neutrophils, which may have contributed to prolonged mucin expression. These results show that chronic allergy-induced mucous metaplasia of Clara cells affects their defensive mechanisms. However, anti-inflammatory treatments were able to re-establish the normal phenotype of Clara cell, with MK being more efficient at restoring a normal profile than BUD. This study highlights the role of epithelial cells in lung injuries and their contribution to anti-inflammatory therapies.

Albuterol modulates its own transepithelial flux via changes in paracellular permeability.

Although inhaled bronchodilators are commonly used in the treatment of airway disease to dilate airway smooth muscle, little is known regarding the mechanisms that regulate albuterol movement across the epithelium to reach its target, the airway smooth muscle. Because the rate of onset depends on the transepithelial transport of albuterol, to determine the mechanisms that regulate the transepithelial movement of albuterol is essential. Human bronchial epithelial cells, fully redifferentiated in culture at the air-liquid interface, were used to study the cellular uptake and total transepithelial flux of (3)H-albuterol from the apical to the basolateral surfaces. (3)H-mannitol and transepithelial electrical resistance were used to quantify changes in paracellular permeability. The majority of albuterol flux across the epithelium occurred via the paracellular route. The cellular uptake of albuterol was found to be saturable, whereas transepithelial flux was not. Cellular uptake could be inhibited by the amino acids lysine and histidine, with no effect on net transepithelial flux. Transepithelial flux was altered by maneuvers that collapsed or disrupted intercellular junctions. Acidification, usually seen in exacerbations of airway disease, decreased albuterol flux. In addition, albuterol increased its own paracellular permeability. The ability of albuterol to modulate paracellular permeability was blocked by the ß(2)-adrenergic receptor-selective antagonist ICI 118551. Albuterol mainly crosses the epithelium via the paracellular pathway, but has the ability to modulate its own permeability through changes in the leakiness of tight junctions, which is modulated through the signaling of the ß(2)-adrenergic receptor.

Acute inflammation promotes early cellular stimulation of the epithelial and stromal compartments of the rat prostate.

BACKGROUND: It has been proposed that prostatic inflammation plays a pivotal role in the pathophysiology of benign hyperplasia and prostate cancer. However, little information is available about the prostatic reaction to bacterial compounds in vivo. Our aim was therefore to evaluate the early effects of bacterial infection on rat ventral prostate compartments. METHODS: Using a rat model of acute bacterial prostatitis by Escherichia coli, we analyzed the histological and ultrastructural changes in the prostate at 24, 48, and 72 hr postinfection. Prostatic tissues were immunostained for prostatic binding protein (PBP), ACTA2, ErbB1, and ErbB2 receptors, TUNEL, and markers of cell proliferation. Dot and Western blots for PBP, ACTA2, ErbB1, ErbB2, and TGFbeta1 were also performed. RESULTS: The prostatic epithelium became hypertrophied, with increases in PBP and ErbB1 expression at 24 hr postinfection. Moreover, inflammation induced the expression of ErbB2, a receptor strongly involved in carcinogenesis. These alterations were more pronounced at 48 hr, but the epithelium also showed apoptosis and finally atrophy at 72 hr postinfection, with a decrease in PBP and ErbB receptors. Interestingly, the epithelial cells exhibited a high level of proliferation in response to the bacteria. The stromal reaction to acute inflammation was initially characterized by smooth muscle hypertrophy. Afterwards, muscle cells acquired a secretory phenotype, with a reduction in ACTA2 at 72 hr postinfection. CONCLUSIONS: Prostatic inflammation, even at the early stages, promotes atrophic and proliferative changes, and the upregulation of ErbB receptors together with dedifferentiation of smooth muscle cells. These data suggest that repetitive reinfections could lead to uncontrolled growth in the prostate gland.

Toll-like receptor 4 in rat prostate: modulation by testosterone and acute bacterial infection in epithelial and stromal cells.

The prostate gland is the most inflammation-prone organ in the male reproductive tract. However, little information is available regarding the immunobiology of this gland. Toll-like receptor 4 (TLR4) is considered to be a major sensor of danger signals and a key trigger of the innate immune responses. TLRs have also been implicated in the development of different inflammatory diseases in organs in which epithelial-stromal interactions are critical for homeostasis. The purpose of this work was to evaluate the presence and regulation of TLR4 in the rat prostate. Western blot and immunocytochemical studies revealed that constitutive expression of TLR4 in the rat ventral prostate was localized in the epithelial cells, mainly associated with the rough endoplasmic reticulum, as well as in smooth muscle cells in the stroma. In addition, increased concentrations of TLR4 were found in castrated rats, predominantly in hypertrophied smooth muscle cells. On the other hand, using a bacterial prostatitis model, we observed an increment in the TLR4 cytoplasmic content and migration of this receptor to the apical plasmatic membranes of epithelial cells at 24 h and 48 h post-infection. These findings suggest that the prostate gland is able to recognize pathogens and to initiate immune responses. In addition, TLR4 appears to be implicated in the vital stromal-epithelial interactions that maintain prostate homeostasis during prostatitis, as well as following androgen deprivation.

Soluble p-cadherin found in human semen.

Cadherins constitute a family of calcium-dependent cell-cell adhesion molecules. P (placental)-cadherin is a 118-kd protein expressed by basal cells in epithelial tissues. P-cadherin also has been described as a soluble protein in certain biological fluids, including human serum and breast milk. Here, we report the presence of an 80-kD fragment of P-cadherin in human semen. No significant differences were found in semen samples from fertile and nonfertile patients. Our results add evidence to previous data indicating that soluble fragments of P-cadherin have a widespread distribution in bodily fluids and suggest that soluble P-cadherin might have functions other than basal epithelial cell-cell adhesion.