Alison J. Weir

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.

Tracheal submucosal gland development in the rhesus monkey,Macaca mulatta: ultrastructure and histochemistry

SummaryThe submucosal glands are thought to be the primary source of the mucus overlying the primate trachea and conducting airways. This study characterizes the development of submucosal glands in the trachea of the rhesus monkey. Tracheas from 46 age-dated fetal, 8 postnatal and 3 adult rhesus were fixed in glutaraldehyde/paraformaldehyde and slices processed for electron microscopy. The earliest (70 days gestational age (DGA)) indication of gland development was the projection of a group of closely packed electron lucent cells with few organelles and small pockets of glycogen into the submucosa. This configuration was observed up to 110 DGA. In fetuses younger than 87 DGA it was present almost exclusively over cartilaginous areas. Between 80 and 140 DGA, a cylinder of electron lucent cells projected into the submucosal connective tissue perpendicular to the surface. In fetuses younger than 100 DGA, it was restricted to cartilaginous areas. By 90 DGA, some glycogen containing cells in proximal regions contained apical cored granules. By 106 DGA, cells in proximal areas contained apical electron lucent granules. More distal cells had abundant GER and electron dense granules. The most distal cells resembled the undifferentiated cells at younger ages. Ciliated cells were present in the most proximal portions of glands at 120 DGA. This glandular organization was found in older animals, including adults, with the following changes: (1) abundance of proximal cells with electron lucent granules increased; (2) abundance of distal cells with electron dense granules increased; and (3) abundance of distal cells with abundant glycogen and few organelles decreased. We conclude that submucosal gland development in the rhesus monkey: (1) is primarily a prenatal process; (2) occurs first over cartilage; (3) continues into the postnatal period; and (4) involves secretory cell maturation in a proximal to distal sequence with mucous cells differentiating before serous cells.

Differential expression of stress proteins in nonhuman primate lung and conducting airway after ozone exposure.

The presence of seven stress proteins including various heat shock proteins [27-kDa (HSP27), 60-kDa (HSP60), 70-kDa (HSP70) and its constitutive form HSC70, and 90-kDa (HSP90) HSPs] and two glucose-regulated proteins [75-kDa (GRP75) and 78-kDa (GRP78) GRPs] in ozone-exposed lungs of nonhuman primates and in cultured tracheobronchial epithelial cells was examined immunohistochemically by various monoclonal antibodies. Heat treatment (42°C) resulted in increased HSP70, HSP60, and HSP27 and slightly increased HSC70 and GRP75 but no increase in GRP78 in primary cultures of monkey tracheobronchial epithelial cells. Ozone exposure did not elevate the expression of these HSPs and GRPs. All of these HSPs including HSP90, which was undetectable in vitro, were suppressed in vivo in monkey respiratory epithelial cells after ozone exposure. Both GRP75 and GRP78 were very low in control cells, and ozone exposure in vivo significantly elevated these proteins. These results suggest that the stress mechanism exerted on pulmonary epithelial cells by ozone is quite different from that induced by heat. Furthermore, differences between in vitro and in vivo with regard to activation of HSPs and GRPs suggest a secondary mechanism in vivo, perhaps related to inflammatory response after ozone exposure.

Acute injury to differentiating Clara cells in neonatal rabbits results in age-related failure of bronchiolar epithelial repair.

Nonciliated bronchiolar (Clara) cells are progenitor cells during lung development. During differentiation, they have a heightened injury susceptibility to environmental toxicants bioactivated by cytochrome P450 monooxygenase. When neonatal rabbits are treated with the P450-mediated cytotoxicant 4-ipomeanol (IPO), abnormal bronchiolar epithelium results. This study establishes the impact of IPO cytotoxicity on 3 stages of rabbit Clara cell differentiation, early (2.5 and 5 days postnatal [DPN]), intermediate (7 and 9 DPN), and late (15 and 21 DPN), and relates the cytotoxicity to the extent of bronchiolar repair. Neonates received a single dose of IPO (5 mg/kg) and were assessed by qualitative pathology 48 hours later for injury or at 4 weeks for repair. IPO injured the 3 stages of Clara cell differentiation to the same degree; epithelium was swollen, exfoliated, and squamated. Epithelial repair differed among the 3 stages. Bronchioles of animals treated during early and intermediate stages had simple squamous and irregularly shaped cuboidal cells. Animals treated during late stages were similar to controls. Thus, differentiating Clara cells are susceptible to injury by the P450-mediated cytotoxicant IPO, but the extent of repair varies based on when the initial injury occurs.

Neonatal Clara cell toxicity by 4-ipomeanol alters bronchiolar organization in adult rabbits

Nonciliated bronchiolar (Clara) cells metabolize environmental toxicants, are progenitor cells during development, and differentiate postnatally. Because differentiating Clara cells of neonatal rabbits are injured at lower doses by the cytochrome P-450-activated cytotoxicant 4-ipomeanol than are those of adults, the impact of early injury on the bronchiolar epithelial organization of adults was defined by treating neonates (3-21 days) and examining them at 4-6 wk. Bronchiolar epithelium of 6-wk-old animals treated on day 7 was most altered from that of control animals. Almost 100% of the bronchioles were lined by zones of squamous epithelial cells. Compared with control animals, the distal bronchiolar epithelium of 4-ipomeanol-treated animals had more squamous cells (70-90 vs. 0%) with a reduced overall epithelial thickness (25% of control value), fewer ciliated cells (0 vs. 10-20%), a reduced expression of Clara cell markers of differentiation (cytochrome P-4502B, NADPH reductase, and 10-kDa protein), and undifferentiated nonciliated cuboidal cell ultrastructure. We conclude that early injury to differentiating rabbit Clara cells by a cytochrome P-450-mediated toxicant inhibits bronchiolar epithelial differentiation and greatly affects repair.

Ultrastructural morphometric characterization of alveolar type II cells of perinatal sheep: a comparison with adults

SummaryThe quantitative morphologic changes in alveolar type II cells during the perinatal period were characterized morphometrically in the lungs of fetal lambs at 132, 138, and 147 days gestational age (DGA) and in newborns at 2 days postnatal age (2 DPN). Ultrastructural features were compared with those of type II cells of ewes 365 days old. Lamellar body profile number per type II cell profile was highest at term (147 DGA) and 2 DPN. In adults, the number of lamellar body profiles and volume density of lamellar bodies were equal to those of the 132 DGA fetus. Multivesicular bodies were most common at 138 DGA and in adults. The volume density of cytoplasmic glycogen fell dramatically during the latter part of gestation. The volume density of many cellular organelles increased to the level observed in adults by term (147 DGA). Subcellular composition of type II cells of adult sheep differs from that reported for adult rats chiefly by the volume density of lamellar material within the cytoplasm. Plate-like or globe-like inclusions were present only in the type II cells of adults. Cytoplasmic extensions of the type II cell crossing the basal lamina were most abundant in the 132 and 138 DGA fetal sheep. Cytoplasmic extensions were rare in adults. We conclude that morphologic changes of the alveolar type II cell associated with gestational age follow a species-specific time course. In the sheep, this occurs during the later part of gestation and extends into the neonatal period. Morphologic and morphometric changes appear to correspond with cellular interactions between alveolar type II cells and mesenchymal cells of the interstitium.