Lung effects of inhaled corticosteroids in a rhesus monkey model of childhood asthma.

BACKGROUND: The risks for infants and young children receiving inhaled corticosteroid (ICS) therapy are largely unknown. Recent clinical studies indicate that ICS therapy in pre-school children with symptoms of asthma result in decreased symptoms without influencing the clinical disease course, but potentially affect postnatal growth and development. The current study employs a primate experimental model to identify the risks posed by ICS therapy. OBJECTIVE: To (1) establish whether ICS therapy in developing primate lungs reverses pulmonary pathobiology associated with allergic airway disease (AAD) and (2) define the impact of ICS on postnatal lung growth and development in primates. METHODS: Infant rhesus monkeys were exposed, from 1 through 6 months, to filtered air (FA) with house dust mite allergen and ozone using a protocol that produces AAD (AAD monkeys), or to FA alone (Control monkeys). From three through 6 months, the monkeys were treated daily with ICS (budesonide) or saline. RESULTS: Several AAD manifestations (airflow restrictions, lavage eosinophilia, basement membrane zone thickening, epithelial mucin composition) were reduced with ICS treatment, without adverse effects on body growth or adrenal function; however, airway branching abnormalities and intraepithelial innervation were not reduced. In addition, several indicators of postnatal lung growth and differentiation: vital capacity, inspiratory capacity, compliance, non-parenchymal lung volume and alveolarization, were increased in both AAD and Control monkeys that received ICS treatment. CONCLUSIONS AND CLINICAL RELEVANCE: Incomplete prevention of pathobiological changes in the airways and disruption of postnatal growth and differentiation of airways and lung parenchyma in response to ICS pose risks for developing primate lungs. These responses also represent two mechanisms that could compromise ICS therapy's ability to alter clinical disease course in young children.

Smooth muscle hypertrophy in distal airways of sensitized infant rhesus monkeys exposed to house dust mite allergen.

BACKGROUND: Airway smooth muscle hypertrophy is closely associated with the pathophysiology of hyper-reactive airways in allergic asthma. OBJECTIVE: To determine whether repeated exposure to allergens during postnatal lung development promotes remodelling of airway smooth muscle. METHODS: Infant, male rhesus monkeys (30-day-old) were sensitized to house dust mite allergen (HDMA) and then exposed to HDMA aerosol periodically over 5 months. Smooth muscle mass and bundle size and abundance in conducting airways were measured and compared with age-matched control (filtered air-exposed) monkeys. RESULTS: Total smooth muscle mass and average bundle size were significantly greater in the conducting airways of monkeys exposed to HDMA. Smooth muscle bundle abundance was not affected by exposure to HDMA. CONCLUSION: Repeated cycles of allergen exposure alter postnatal morphogenesis of smooth muscle, affecting both total mass and bundle size, in conducting airways of infant monkeys.

The remodelled tracheal basement membrane zone of infant rhesus monkeys after 6 months of recovery.

BACKGROUND: In previous studies, we showed that repeated exposure to (1) house dust mite allergen (HDMA) (Dermatophagoides farinae) caused thickening of the basement membrane zone (BMZ) and (2) HDMA+ozone (O3) caused depletion of BMZ perlecan and atypical development of BMZ collagen (irregular thin areas<2.0 microm in width). OBJECTIVE: The purpose of this study was to determine if these remodelling changes were reversible after 6 months of recovery. METHODS: Rhesus monkeys were exposed to a regimen of HDMA and or O3 or filtered air (FA) for 6 months. After the exposure protocol was completed FA and O3 groups were allowed to recover in FA for 6 months. The HDMA and HDMA+O3 exposure groups recovered in a modified environment. They were re-exposed to HDMA aerosol for 2 h at monthly intervals during recovery in order to maintain sensitization for pulmonary function testing. To detect structural changes in the BMZ, collagen I and perlecan immunoreactivity were measured and compared to data from the previous papers. RESULTS: The remodelled HDMA group had a significantly thicker BMZ and after 6 months of recovery the width had not regressed. In the remodelled BMZ of the HDMA+O3 group, perlecan had returned to the BMZ after 6 months of the recovery protocol, and the thin, irregular, collagen BMZ had been resolved. CONCLUSION: In summary, this study has shown that: (1) The width of the remodelled HDMA BMZ did not regress during a recovery protocol that included a sensitizing dose of HDMA. (2) The atypical collagen BMZ in the HDMA+O3 BMZ was resolved in the absence of O3. (3) Depletion of perlecan from the BMZ by O3 was reversed by recovery in the absence of O3.

Cellular and molecular characteristics of basal cells in airway epithelium.

Basal cells exist as a separate layer of cells covering most of the airway basal lamina. In this central position, they can interact with columnar epithelium, neurons, basement membrane, and the underlying mesenchymal cells. In addition, they interact with inflammatory cells, lymphocytes and dendritic cells. These interactions take place in the lateral intercellular space between basal cells. In this central position basal cells become a very important part of the epithelial-mesenchymal trophic unit of larger airways. In this review it is shown that basal cells may function as progenitor cells of airway epithelium and have a role in attachment of columnar epithelium with the basement membrane. They also have the potential to function in regulation of neurogenic inflammation, the inflammatory response, transepithelial water movement, oxidant defense of the tissue and formation of the lateral intercellular space. Other characteristics of basal cells were not clearly associated with a particular function. The functions for basal cells listed attempt to explain the presence of recently identified molecules in basal cells of airway epithelium. It should be pointed out that specific studies have not been carried out which test the relationship between the molecular functions we describe in this review and the basal cell in airway epithelium.

Early events in naphthalene-induced acute Clara cell toxicity. II. Comparison of glutathione depletion and histopathology by airway location.

One of the presumed roles of intracellular glutathione (GSH) is the protection of cells from injury by reactive intermediates produced by the metabolism of xenobiotics. To establish whether GSH depletion is a critical step in the initiation of events that lead to cytotoxicity by P450-activated cytotoxicants, naphthalene, a well-defined Clara cell cytotoxicant, was administered to mice (200 mg/kg) by intraperitoneal injection. Shortly after injection (1, 2, and 3 h), intracellular GSH content was assessed by high performance liquid chromatography or quantitative epifluorescent imaging microscopy and compared with the degree of cytotoxicity as assessed by high resolution histopathology. In highly susceptible airways (distal bronchioles), GSH decreased by 50% in 1 h. Cytoplasmic vacuolization was not visible until 2 h, when GSH had decreased by an additional 50%. By 3 h, cytoplasmic blebbing was extensive. In minimally susceptible airways (lobar and proximal bronchi), GSH depletion varied widely within the population; a small proportion of the cells lost greater than 50% of their GSH by 2 h and a significant percentage of the cells retained most of their GSH throughout the entire 3 h. Cytoplasmic vacuolization was apparent in some of the cells at 2 h but not visible in any cells at 3 h. We conclude that (1) loss of intracellular GSH is an early event that precedes initial signs of cellular damage in Clara cell cytotoxicity; (2) this pattern of loss in relation to early injury is found both in highly susceptible and minimally susceptible airway sites; (3) there is wide cell-to-cell heterogeneity in the response; (4) the heterogeneity in the response profile varies between populations in highly susceptible and minimally susceptible sites; and (5) once the intracellular GSH concentration within the entire cell population drops below a certain threshold, the initial phase of injury becomes irreversible.

Allergic asthma induced in rhesus monkeys by house dust mite (Dermatophagoides farinae).

To establish whether allergic asthma could be induced experimentally in a nonhuman primate using a common human allergen, three female rhesus monkeys (Macaca mulatta) were sensitized with house dust mite (Dermatophagoides farinae) allergen (HDMA) by subcutaneous injection, followed by four intranasal sensitizations, and exposure to allergen aerosol 3 hours per day, 3 days per week for up to 13 weeks. Before aerosol challenge, all three monkeys skin-tested positive for HDMA. During aerosol challenge with HDMA, sensitized monkeys exhibited cough and rapid shallow breathing and increased airway resistance, which was reversed by albuterol aerosol treatment. Compared to nonsensitized monkeys, there was a fourfold reduction in the dose of histamine aerosol necessary to produce a 150% increase in airway resistance in sensitized monkeys. After aerosol challenge, serum levels of histamine were elevated in sensitized monkeys. Sensitized monkeys exhibited increased levels of HDMA-specific IgE in serum, numbers of eosinophils and exfoliated cells within lavage, and elevated CD25 expression on circulating CD4(+) lymphocytes. Intrapulmonary bronchi of sensitized monkeys had focal mucus cell hyperplasia, interstitial infiltrates of eosinophils, and thickening of the basement membrane zone. We conclude that a model of allergic asthma can be induced in rhesus monkeys using a protocol consisting of subcutaneous injection, intranasal instillation, and aerosol challenge with HDMA.

Development of phase II xenobiotic metabolizing enzymes in differentiating murine clara cells.

Glutathione S-transferases (GSTs) and epoxide hydrolases (EHs) protect cells from exogenous insult by detoxifying electrophilic compounds. Little is known about these enzyme systems during postnatal lung development. This study was designed to help establish whether the heightened neonatal susceptibility of the lung to bioactivated cytotoxicants is the result of inadequate ability to detoxify reactive intermediates. We compared the distribution of immunoreactive protein and enzymatic activity of GSTs and EHs in isolated distal airways during pre- and postnatal development in lungs of mice from 16 days gestation to 9 weeks postnatal age (adult). GST alpha, mu, and pi class protein expression in fetal and postnatal lung varied by isozyme and age. Isozymes alpha and mu are expressed at low levels before birth, high levels on postnatal day 7, low levels between postnatal days 14 and 21, high levels at postnatal day 28, and slightly lower levels in adults. Immunoreactive protein of isozyme pi has a peak expression on gestational day 18 and again on postnatal day 4, is undetectable at postnatal day 21, and is at peak levels in the adult mouse lung. GST activity in distal airways increased with age. Microsomal EH protein expression increased in intensity with age, while activity was similar in airways from all ages. We conclude that in the mouse lung (1) cellular expression of glutathione S-transferase varies by age and isozyme and does not increase with increasing age, (2) airway glutathione S-transferase activity increases with increasing age and does not correlate with immunoreactive protein expression, and (3) airway microsomal epoxide hydrolase activity does not increase, even though immunoreactive protein expression does increase with age.

Three-dimensional organization of the lamina reticularis in the rat tracheal basement membrane zone.

The airway basement membrane zone is a region specialized for the attachment of the epithelium with the matrix. The epithelium is attached to the lamina densa, which, in turn, is connected to types I and III collagen of the lamina reticularis with anchoring fibrils. The purpose of this study was to define the three-dimensional organization of the structural proteins of the lamina reticularis in the rat trachea. We approached this problem by using whole mounts to look down on the flat surface of the basement-membrane zone rather than a cross section of its thin profile. Fluorescent microscopy with long working distance water immersion objectives and scanning electron microscopy revealed that the structural proteins are arranged as a mat of large fibers oriented along the longitudinal axis of the airway. Smaller fibers are crosslinked with the larger fibers to complete this structure. Other small fibers are oriented around the large fibers and an amorphous material covers individual fibers. The large fibers oriented along the longitudinal axis of the airway are consistent with prior descriptions of fibers composed of collagen III with some collagen I and V; small fibers encircling the large fibers may be collagen VI. The crosslinking fibers are made up of elastin and probably elastin-associated microfibrils. The amorphous proteins covering the fibrous framework may contain proteoglycans and other nonstructural proteins reported to be in the lamina reticularis. The present studies demonstrate that the structural proteins of the lamina reticularis in the rat trachea are arranged as fibers in a highly organized manner.

In vitro culture of microdissected rat nasal airway tissues.

The surface epithelium lining the nasal airways is a potential target for inhaled contaminants such as ozone, endotoxin, formaldehyde, tobacco smoke, and organic dusts. The epithelial response to injury may depend on the toxicant, the type of epithelium, the severity of the injury, and the presence of inflammatory cells and their secreted products. To study mechanisms of toxicant-induced epithelial injury and repair, in the absence of cellular inflammation or other systemic effects, we have developed a culture system to maintain morphologically distinct nasal airway epithelium in vitro. Microdissected maxilloturbinates and proximal nasal septa of male F344/N rats were cultured at an air-liquid interface for up to 14 d in supplemented serum-free medium. Maxilloturbinates are lined by nonciliated cuboidal nasal transitional epithelium (NTE) with few or no mucous cells. The proximal nasal septum is lined by a mucociliary respiratory epithelium (RE) that normally contains numerous mucous cells. Preservation of the normal RE and NTE phenotype in culture was assessed by light and electron microscopy, and analysis of an airway mucin gene (rMuc-5AC) messenger RNA (mRNA). Both RE and NTE retained normal cell morphology for 14 d in culture (DIC). After 14 DIC there were 20% fewer RE cells in the septa (equal loss of ciliated and mucous cells) and 25% more NTE cells in the maxilloturbinates (increased number of basal cells). Compared with the RE, the NTE expressed consistently low levels of rMuc-5AC mRNA and had little to no histochemically detectable intraepithelial mucosubstances (IM) after 0, 3, 7, or 14 DIC. The amount of stored IM and the steady-state levels of rMuc-5AC mRNA in the RE decreased with time in culture. In summary, this culture system can maintain fully differentiated secretory and nonsecretory rat airway epithelia in vitro for up to 14 d. This study was an essential first step in developing a system to study the pathogenesis of toxicant-induced airway epithelial injury and mechanisms of cellular repair and adaptation in the absence of cellular inflammation and other systemic influences.

Endotoxin potentiates ozone-induced mucous cell metaplasia in rat nasal epithelium.

People are exposed to a combination of environmental pollutants throughout their lives. Repeated exposures of one common pollutant, ozone, have been reported to cause the development of mucous cell metaplasia in the nasal transitional epithelium (NTE) of rats. The present study was designed to test the hypothesis that exposure to bacterial endotoxin, another toxicant ubiquitous to the environment, potentiates this metaplastic response in rat NTE. Rats were exposed to 0 or 0.5 ppm ozone 8 h/day for 3 days. After ozone exposure, rats were intranasally instilled with saline containing 0 or 100 micrograms endotoxin once daily for 2 days. Rats were killed 6 h or 3 days after the last intranasal instillation. Nasal tissue was processed for light microscopy and image analysis, or for isolation of total RNA. Mucous cell metaplasia was not detected in air/endotoxin-exposed rats, was observed in ozone/saline-exposed rats, and was most severe in ozone/endotoxin-exposed rats. At 6 h after instillation, amounts of intraepithelial mucosubstances (IM) were 4-fold greater in NTE of ozone/endotoxin-exposed rats as compared to controls. These IM levels were similar to those of ozone/saline-exposed rats. Mucin-specific mRNA (rMuc-5AC) levels were elevated in all treatment groups at this timepoint. At 3 days after instillation, amounts of IM in ozone/endotoxin-exposed rats were 10-fold greater than in controls and 5-fold greater than in ozone/saline-exposed rats. rMuc-5AC mRNA levels remained elevated in the ozone/endotoxin-exposed rats. Despite the fact that bacterial endotoxin alone does not cause a phenotypic change in rat NTE, it can augment the mucous cell metaplasia induced by a previous exposure to ozone.

Pulmonary cytochrome P450 monooxygenase and Clara cell differentiation in mice.

Various studies indicate that cytodifferentiation of Clara cells and development of pulmonary cytochrome P450 (CYP) monooxygenases occur postnatally. The timing of these events is species-specific. Neonatal mice are more susceptible than adult mice are to Clara cell injury by naphthalene, but little is known about the postnatal development of Clara cells and CYP in mice. This study was designed to determine the developmental pattern of Clara cell differentiation and CYP expression in mice. Lungs from mice aged 16 days gestation to 63 days postnatal (DPN) were studied. Clara cell secretory protein (CC10) expression in nonciliated cells was detected earlier in proximal airways than in distal airways, but reached adult levels at 14 DPN in all airway levels. Cilia-associated tubulin expression closely followed the onset of CC10 expression, as did expression of CYP reductase. CYP2B protein expression appeared and differentiated earlier in bronchi than in bronchioles and reached adult levels at 14 and 28 DPN, respectively. CYP2F2 expression appeared earlier in proximal airways, but did not reach adult levels of expression until after 28 DPN. CYP activity, measured by naphthalene metabolism, increased with age and corresponded to CYP2F2 protein expression. We conclude that in the mouse, (1) Clara cell maturation is a postnatal event, (2) Clara cell differentiation is complete at the same age in proximal and distal airways, (3) CYP reductase protein expression occurs at the same time as CC10 expression, but CYP2B and CYP2F2 lag behind, and (4) stereoselective naphthalene monooxygenase activity corresponds with CYP2F2 protein expression.

Naphthalene cytotoxicity of differentiating Clara cells in neonatal mice.

Selective Clara cell injury produced by many bioactivated lung toxicants is thought to result from high levels of activating enzymes found in differentiated Clara cells. A recent study found an elevated susceptibility to the Clara cell toxicant 4-ipomeanol in neonatal rabbits when Clara cell P450 activity is low. To determine whether differentiating Clara cells in another species (mouse) are more susceptible to injury by a different bioactivated Clara cell toxicant (naphthalene), adult, 14-day postnatal (DPN) and 7DPN male mice were given a single intraperitoneal dose (25, 50, or 100 mg/kg) of naphthalene and killed 24 hr later. Epithelial damage, as assessed by quantitative histopathology, included cellular swelling, vacuolization, and exfoliation. In 7DPN mice, bronchiolar epithelium was severely injured at the lowest dose of naphthalene tested, 25 mg/kg. Bronchiolar epithelium in 14DPN mice was moderately injured at 25 mg/kg; injury severity was greatest at 50 and 100 mg/kg. Minimal bronchiolar epithelial injury occurred in adult mice at 50 mg/kg and moderate injury at 100 mg/kg. In proximal bronchi, epithelium of 7DPN mice showed signs of injury only at 100 mg/kg. Bronchial epithelium of adult mice was not injured at any dose. Isolated distal airways from 7DPN and 14DPN mice were more sensitive to naphthalene exposure than isolated distal airways from adult mice. Despite the low levels of P450 activity, differentiating Clara cells in neonatal mice are more susceptible to injury by the bioactivated cytotoxicant naphthalene than are differentiated Clara cells in adult mice.