Preservation of alveolar type II pneumocyte lamellar bodies for electron microscopic studies.

Simultaneous fixation with glutaraldehyde and osmium tetroxide, followed by an uranyl acetate (UA) treatment before dehydration and embedding (Hirsch and Fedorko 1968) ensures a very good preservation of lamellar bodies (LB's) as well as of the cellular membranes in type II pneumocyte. The uranyl acetate treatment appeared to be the most efficient step of the procedure. The morphological aspect of lamellar bodies after such a preparation was similar to that observed after freeze-etching of lipid retaining methods. Moreover, the Hirsch-Fedorko procedure is very simple and can easily be used for routine ultrastructural and radioautographic studies. On the other hand, it appeared that the uranyl acetate phospholipid "complex" is very sensitive to the pH of chemical solutions used after sectioning. The "complex" is variously dissolved by alkaline solutions, photographic developers or stains. The best preservation of ultrastructure was obtained with neutral or acidic developers and acidic stains.

Evolution of mesenchymal cells in fetal rat lung.

The evolution of connective tissue cells in the developing fetal rat lung is studied under the electron microscope from the 15th until the 21st day of gestation and is compared to the evolution of epithelial cells. Three successive types of stem cells ("mesocytoblasts") are present during the first stages of lung development studied (15 to 18 days of gestation). These stem cells appear to be able to differentiate into fibroblasts or into smooth muscle cells, according to their localization along the broncho-alveolar tubule. Myoblasts are situated near the bronchial epithelium, whereas fibroblasts occur under the alveolar epithelium. Epithelo-mesenchymal interactions are assumed to play a role in this differentiation process. Synthesis of both, collagen and elastic fibers and of cytoplasmic filaments by fibroblasts as well as by myoblasts reveal the multiple potentialities of the mesenchymal stem cell and suggest a common origin. The early fibroblast in characterized by long cytoplasmic processes which contain numerous cytofilaments, and by the presence of collagen fibers in the vicinity of the cell. Later on, (20 days of gestation) the mature fibroblast of the lung mesenchyme shows areas of RER, glycogen and lipidic vacuoles in its cytoplasm. Cytofilaments are numerous within very long cytoplasmic processes and elastic and collagen fibers are very frequent beside the cytoplasmic membrane. The earliest fibroblast differentiation occurs under the epithelium of primitive respiratory bronchioles, which indicate the limit between the bronchial and the alveolar territories. Later on, differentiating fibroblasts are found throughout the whole alveolar walls. Connective tissue cells other than mesenchymal stem cells, fibroblasts or myoblasts are observed during lung development. Vacuolar cells, similar to Hofbauer cells, transiently appear on the 16th day of gestation. On the 20th and the 21st day macrophage-like cells are present in the septal space of the alveolar wall. The absence of intermediate stages of differentiation and parallel evolution of blood cells suggest that those connective tissue cells are differentiated elsewhere and have then migrated from blood into lung mesenchyme. No cell death has been observed in the developing lung.

Morphological aspects of type II alveolar pneumocytes following treatment with puromycin in vivo.

Ultrastructural modifications of type II pneumocytes (PNM-II) in mice were analysed 125 and 155 minutes after puromycin treatment (12 mg/100 gm at 0, 30, 60 and 90 minutes). A quantitative evaluation of the cell compartments was carried out and the inhibition of protein synthesis in PNM-II was monitored by light microscopic radioautography, following 3H-leucine injection. In electron micrographs, following a 125-minute puromycin treatment, the number and size of lamellar bodies, the precursors of lung surfactant material appeared markedly reduced. The multivesicular bodies (MVB), which are normally very frequent in PNM-II, had almost completely disappeared, as had composite bodies. Golgi saccules were dilated, while the area occupied by Golgi vesicles was enlarged. Observations following the 155-minute puromycin treatment showed a strong enhancement of these modifications. Smooth and coated vesicles of the Golgi area, as well as peroxisomes, did not appear modified by puromycin. Elongated zones of autophagy were more prevalent after 125-minute treatment than after the 155-minute one. Small bodies were frequently observed in the cytoplasm, near the Golgi zone. They were bounded by a smooth membrane and contained tiny vesicles and/or electron-dense lamellae similar to those present within the lamellar bodies. Parallel membranes formed folds, some of them in continuity with lamellar bodies, thus encircling portions of cytoplasm. These structures, which were few in number in controls, were very frequently observed in treated cells, mainly after the 125-minute treatment. These extensive alterations of PNM-II morphology appeared to be related to a disturbed production of pulmonary surfactant.

Proliferation and differentiation of brown adipocytes from interstitial cells during cold acclimation.

The mechanisms of brown adipocyte proliferation and differentiation during cold acclimation (and/or adaptation to hyperphagia) have been studied by quantitative photonic radioautography. [3H]thymidine was injected to warm-acclimated (25 degrees C) rats and to animals exposed to 5 degrees C for 2 days. Samples of interscapular brown adipose tissue were collected for quantitative analysis of mitotic frequencies at various periods of time (4 h-15 days) after the injection of [3H]thymidine, the rats being maintained at the temperatures to which they were initially exposed. Confirming our previous results [Bukowiecki et al., Am. J. Physiol. 242 (Endocrinol. Metab. 5): E353-E359, 1982], it was found that cold exposure for 2 days markedly enhanced mitotic activity in endothelial cells, interstitial cells, and brown preadipocytes rather than in fully differentiated brown adipocytes. The total tissue labeling index (percent of labeled nuclei) increased approximately 70 times over control values. We now report that cellular labeling progressively increased in mature brown adipocytes during cold acclimation, whereas it correspondingly decreased in interstitial cells and brown preadipocytes. This indicates that the sequence of events for cellular differentiation is interstitial cells----brown preadipocytes----mature brown adipocytes. Remarkable, labeling frequency did not change in endothelial cells during cold acclimation demonstrating that these cells cannot be considered as progenitors of brown adipocytes. It is suggested that brown adipocyte proliferation and differentiation from interstitial cells represent the fundamental phenomena explaining the enhanced capacity of cold-acclimated and/or hyperphagic rats to respond calorigenically to catecholamines.

Role of sympathetic innervation in brown adipocyte proliferation.

The role of sympathetic nerves in the control of brown adipose tissue (BAT) growth was studied by quantitative photonic autoradiography using [3H]-thymidine to follow mitotic activity. The effects of cold exposure (4 days at 5 degrees C) and chronic norepinephrine treatment (0.375 mumol/h for 4 days at 25 degrees C) were compared in intact and denervated interscapular BAT pads of adult rats. The denervated pads were paler than the contralateral innervated sides and contained numerous adipocytes filled with large lipid droplets. In the innervated BAT pad, cold exposure markedly enhanced the labeling frequency in brown adipocyte precursor cells (interstitial cells and preadipocytes) and in endothelial cells forming the numerous blood capillaries (P < 0.01). However, in the denervated BAT pads, the effects of cold exposure on cell proliferation were markedly inhibited. Remarkably, norepinephrine infusion at 25 degrees C mimicked the effects of cold exposure on the coordinated proliferation of the different cellular types, both in the innervated and denervated pads. These results demonstrate that intact sympathetic nerves are required for the stimulation of mitotic activity in BAT by cold exposure but not by norepinephrine infusion. It appears therefore that norepinephrine release from sympathetic nerves represents the initial stimulus in a chain of metabolic events leading to BAT hyperplasia. However, sympathetic or sensory nerves may still contain factors modulating cell proliferation and differentiation in BAT.

Major thermogenic defect associated with insulin resistance in brown adipose tissue of obese diabetic SHR/N-cp rats.

The effects of norepinephrine and insulin on thermogenesis were investigated in adipocytes isolated from brown adipose tissue (BAT) of obese non-diabetic LA/N-cp rats (obese LA), obese diabetic SHR/N-cp rats (obese SHR), and their corresponding lean controls. The maximal calorigenic response (Vmax) and the sensitivity [50% effective concentration (EC50)] to norepinephrine (1 microM) were markedly reduced in brown adipocytes from obese SHR rats compared with their lean controls (3- to 4-fold decrease in the Vmax and 50% increase in the EC50 value). In the same cells, there was a similar decrease in the respiratory response to dibutyryl adenosine 3',5'-cyclic monophosphate, indicating the presence of a major postreceptor defect. Remarkably, total BAT cytochrome oxidase activity (an index of cellular mitochondrial content) was also diminished three to four times in obese SHR rats, suggesting that a reduced BAT mitochondrial content is responsible for the decreased thermogenesis. Ultrastructural studies revealed that the cytoplasm of brown adipocytes from obese SHR rats contained a large lipid droplet, numerous tiny droplets, and few atypical mitochondria with loosely packed cristae. Adipocytes from obese SHR rats were also characterized by a significant resistance to the antithermogenic effect of insulin but not to that of the nonmetabolizable adenosine analogue N6-phenylisopropyl adenosine. In contrast, all the above biochemical parameters were normal in obese LA rats. These results demonstrate that the marked insulin resistance in BAT of obese SHR rats is associated with a decreased responsiveness and sensitivity to norepinephrine, indicating the presence of receptor and postreceptor defects. It is suggested that insulin resistance and/or diabetes in SHR/N-cp rats lead to a decreased mitochondriogenesis in BAT, which results in a reduced thermogenic capacity, thereby contributing to the development of obesity.

Brown adipose tissue hyperplasia: a fundamental mechanism of adaptation to cold and hyperphagia.

Cold acclimation (4 degrees C) and "cafeteria diets" increased the thermic response of rats to catecholamines. This phenomenon was accompanied by six- to eightfold increases of interscapular brown adipose tissue (IBAT) weight, total tissue cytochrome oxidase activity, and total number of brown adipocytes. Quantitative radioautographic experiments using [3H]thymidine disclosed that cold exposure markedly enhanced the mitotic activity in blood capillaries and small-venule endothelial cells, adipose tissue interstitial cells, and preadipocytes rather than in fully differentiated brown adipocytes. IBAT mitotic index increased 70 times over control values after only 2 days of cold exposure. Thereafter, the proliferative activity progressively decreased. IBAT cell composition was modified during cold acclimation as the percentage of interstitial cells and preadipocytes increased over the other cellular types. Because brown adipose tissue is the principal site of norepinephrine-induced thermogenesis in homeothermal animals, it is suggested that brown adipocyte proliferation from precursor cells represents the fundamental phenomenon explaining the increased capacity of cold-acclimated animals to respond calorigenically to catecholamines.

In vivo differentiation of brown adipocytes in adult mice: an electron microscopic study.

The differentiation of brown adipocyte precursor cells was studied in interscapular brown adipose tissue of adult mice by electron microscopy. Different stages of cell differentiation were characterized in situ. Previous autoradiographic studies suggested that interstitial cells represent the precursor cells of fully differentiated brown adipocytes. The present observations provide morphological evidence for a progressive differentiation of interstitial stem cells into mature brown adipocytes. Four typical stages of development were identified: (1) interstitial cells, (2) protoadipocytes, (3) preadipocytes, and (4) mature brown adipocytes. Interstitial stem cells were small spindle shaped cells, situated between brown adipocytes and characterized by a high nuclear-cytoplasmic ratio, the scarcity of organelles, and the absence of lipid inclusions. Protoadipocytes resembled interstitial cells except that they contained a few tiny lipid droplets in their cytoplasm. Preadipocytes had a larger cytoplasm enclosing many mitochondria and lipid droplets; the smooth endoplasmic reticulum was well developed surrounding the lipid droplets, and was closely associated with the mitochondria. Preadipocytes had the typical structure of growing cells, developing long cytoplasmic processes between and around blood capillaries. Mature brown adipocytes represented the final stage of differentiation. Almost all their cellular volume was occupied by lipid droplets and numerous mitochondria with very dense cristae. Brown adipocytes were also characterized by a tight association with blood capillaries, as expected from metabolically active cells requiring oxygen and substrates. These observations provide direct ultrastructural evidence for a progressive differentiation of interstitial cells into brown adipocytes with a continuum of intermediate cellular types.

Experimental oral candidosis in the mouse: microbiologic and histologic aspects.

A model of oral candidosis was developed in order to investigate histologic and microbiologic aspects of this host-parasite interaction under controlled experimental conditions. Normal adult CD-1 mice were inoculated by the topical application of 10(8) Candida albicans blastospores, and oral colonization was monitored by the quantitative culturing of saliva samples and of digested oral mucosa. Tissue sections of the mucosa were examined in a kinetic study ranging from 2 h to 13 days postinoculation. We report here that oral colonization by C. albicans can be induced in normal adult mice without the use of any compromising agent and that the animals recover from this mucosal infection following a reproducible pattern. Temporal analysis of the oral histopathology showed that distinct patterns of inflammation are associated with particular stages in the development of the infectious foci. This experimental model offers a means of further investigating the host-parasite interactions involved in the onset and development of oral candidosis.

Beta-adrenergic stimulation of brown adipocyte proliferation.

The mechanisms of brown adipose tissue (BAT) growth were studied by quantitative photonic radioautography using tritiated thymidine to follow mitotic activity. To identify the nature of the adrenergic pathways mediating brown adipocyte proliferation and differentiation, the effects of cold exposure (4 days at 4 degrees C) on BAT growth were compared with those induced by treating rats at 25 degrees C with norepinephrine (a mixed agonist), isoproterenol (a beta-agonist), and phenylephrine (an alpha-agonist). The drugs were continuously administrated via osmotic minipumps (0.375 mumol/h during 4 days) implanted subcutaneously. Cold exposure markedly enhanced the mitotic activity in brown adipocyte precursor cells (interstitial cells and preadipocytes) and endothelial cells forming the numerous capillaries. Norepinephrine mimicked the effects of cold exposure, not only on the mitotic activity, but also on the distribution of the labeling among the various cellular types. Isoproterenol entirely reproduced the effects of norepinephrine both on the labeling index and on the cellular type labeling frequency. In contrast, phenylephrine did not stimulate cell division. These results demonstrate that norepinephrine triggers a coordinated proliferation of brown adipocytes and endothelial cells in warm-exposed rats that is similar to that observed after cold exposure. They also suggest that cold exposure stimulates BAT growth by increasing the release of norepinephrine from sympathetic nerves and that the neurohormone activates mitoses in BAT precursor cells via beta-adrenergic pathways.

Insulin stimulates in vivo cell proliferation in white adipose tissue.

The effects of insulin on white adipose tissue hyperplasia have been studied by quantitative radioautography in streptozotocin diabetic rats. After 1 mo of diabetes, the majority of the adipocytes were extremely small (less than 15 microM) but contained several tiny triglyceride droplets (pauciadipose cells). At this point, the diabetic animals were infused with insulin (8.5 U.kg-1.day-1) delivered via osmotic minipumps for 0-8 days. Control and diabetic rats were pulse-injected with tritiated thymidine (4 h), and samples of parametrial white adipose tissue (PWAT) were collected for quantitative analysis of mitotic frequencies. One-day insulin treatment increased PWAT weight and adipocyte size without stimulating mitoses. However, after 4 days of insulin replacement, the total tissue labeling index increased greater than 120 times over control values. This marked enhancement of mitotic activity principally occurred in interstitial cells rather than in typical adipocytes, pauciadipose cells, or endothelial cells. After 8 days of insulin infusion, the mitotic activity significantly decreased. The results demonstrate that 1) insulin is able to stimulate cell proliferation in PWAT of adult diabetic rats, 2) it transiently stimulates proliferative activity in adipose tissue after a 2- to 3-day period of induction, 3) the increase in adipocyte size precedes the enhancement of mitotic activity, and 4) the effects of insulin were specific, as in the same rats, under the same experimental conditions, insulin did not increase the cell labeling in brown adipose tissue.