We assessed the potential role of all-trans-retinoic acid on the developing chick pancreas, specifically with regard to the proportions of insulin cells. The endodermal component of the dorsal pancreatic bud of 5-d-old chick embryos was cultured on Matrigel. Retinoic acid (10⁻⁶ or 10⁻⁵ M) was added to a standard serum-free medium, Ham's F12 containing insulin, transferrin and selenium (F12.ITS). Control grafts were cultured in F12.ITS alone or in F12.ITS with DMSO (the diluent for retinoic acid). After 7 d the explants were retrieved, freeze-dried, vapor-fixed, and embedded in resin. Endocrine cell types were identified by immunocytochemistry. The numbers of insulin cells were expressed as a proportion of the sum of insulin plus glucagon cells. Retinoic acid had a dose-related effect; the proportion of insulin cells in explants treated with the lower dose of retinoic acid (10⁻⁶ M) was more than twice the proportion of insulin cells in explants treated with the higher dose (10⁻⁵ M) of retinoic acid and more than three times that of the control grafts.

The recent identification of numerous matrix genes and gene products has allowed a detailed examination of their roles in development. Two of these extracellular matrix proteins, fibrillin-1 and fibrillin-2, are components of the elastin-associated microfibrils. Given what is known about the distribution of the fibrillins in normal tissues and the abnormalities that result when mutations occur, a basic hypothesis has emerged: fibrillin-1 is primarily responsible for load bearing and providing structural integrity, whereas fibrillin-2 may be a director of elastogenesis. Nevertheless, examination of phenotypes in disorders caused by mutations in fibrillin-1 or fibrillin-2 suggests some common functions. To better understand these similar and diverse roles, it would be helpful to examine these proteins during chick development. To accomplish this goal, it is first necessary to characterize the chick homologs of the known fibrillins. In this study, the partial chick FBN1 cDNA was identified by polymerase chain reaction-aided cloning as a first step toward elucidating these goals. Sequence analysis indicated that there is striking conservation between chick and mammalian fibrillin-1 at the DNA and protein levels. Antisense and sense riboprobes were synthesized and used in in situ hybridization in stage 14 chick embryos and high levels of FBN1 transcripts were observed in the heart.

We describe the establishment of a continuous, nontransformed cell line obtained from primary culture of a lactating (114 days postparturition) Anglo-Nubian (Capra hircus) goat mammary gland biopsy. These cells (CMEC), have been cultured in the presence of supraphysiologic concentrations of insulin and hydrocortisone for more than 560 population doublings (over 80 passages) without any sign of senescence while maintaining a normal/near-normal diploid chromosome modal number of 2n = 60 and are responsive to contact inhibition of proliferation. Cytoskeletal analysis indicates that CMECs are epithelial, without detectable fibroblastic or myoepithelial cells. When grown at low density on plastic substratum, the cells tend to form island monolayer aggregates with the characteristic cobblestone morphology of epithelial cells. With increasing density, the cells organize into lumen-like structures with various morphology consisting of large and small vacuolized and nonvacuolized cells. Postconfluent cultures form epithelial raised dome-like structures, implying a process of contact-induced differentiation. This is corroborated by positive immunocytochemistry to lactation-specific proteins: β-casein and α-lactalbumin, which were predominantly expressed in dome-forming cells. We also observed an overall modulation of cytokeratin 18/19 expression associated with number of days post subculture and with the expression of lactation-specific proteins. Postconfluent cultures which contain lactation-specific, antibody-reactive, dome-like structures showed a decreased expression of keratin 18 and no (null) expression for keratin 19. Lastly, cells cultured within a collagen matrix show morphological differentiation with the organization of branching duct-like and acini-like structures. This study suggests that CMECs are a useful in vitro model for study of mammary gland development and differentiation, in particular, direct modulation of epithelial cells grown on plastic substratum or extracellular matrix without the influence of stromal elements or the necessity and variability associated with primary cell culture or tissue explants.

Scanning electron microscopy (SEM) observation showed that fully differentiated spherical adipocytes were embraced by a network of collagens and fibroblastic preadipocytes. The properties of both the collagen networks and the preadipocytes allow the adipocytes to be interconnected, forming a fat-cell cluster, which can anchor to the bottom of a culture dish. In this network structure, collagen fibrils and fibrillar bundles were closely arranged and stratified. We found that immunostained collagens appeared to form extracellular network structures, which can be observed by SEM. The extracellular network of fibronectin was the first to develop among the extracellular matrix (ECM) components, though it became degraded with the progress of adipocyte differentiation. The type I collagen network was the last to develop and remained well organized through the late stage of adipocyte differentiation. The extracellular networks of type III, V, and VI collagen developed by the mid-stage and remained in the late stage of adipocyte differentiation. The network structures of type IV collagen and laminin became degraded during the differentiation process and localized at the surface of spherical cells. In addition to these basement membrane components, types III, V, and VI collagens also showed pericellular spherical staining patterns. These results demonstrated that the constitution and distribution of the ECM are altered during adipocyte differentiation, suggesting that the organization of each ECM component into a suitable structure is a requirement for the differentiation and maintenance of unilocular adipocytes.

Primary cultures of the brain from sheep embryos were used to establish cell lines after transfection by the simian virus 40 (SV40) large T gene. Two of the lines (A15 and 4A6) displayed astroglial properties. They expressed the glial fibrillary acidic protein (GFAP), intermediate filament protein vimentin, and S-100 (beta-subunit) protein. While numerous rodent and human glial cell lines are available, this is to our knowledge the first description of ovine cell lines with astrocyte features. In addition, these cell lines were derived from sheep embryos chosen for their genetic susceptibility to scrapie (PrP genotype: VV₁₃₆, QQ₁₇₁). Therefore, they could be attractive tissue culture models for the study of propagation and pathogenesis of the scrapie agent ex vivo.

Simple methods are presented for quantitating contraction and intracellular calcium simultaneously in single, cultured smooth muscle cells. These methods are the first to demonstrate that reliable velocities of cell shortening can be measured in cultured smooth muscle cells and that cells in vitro exhibit shortening velocities comparable to those measured in the fastest phasic muscles in situ. Temporal relationships between changes in intracellular calcium and shortening within single cells were determined with a resolution of 100 ms and were consistent with measures in more “classical” preparations. Intracellular calcium rose quickly and transiently 10-fold above the basal level of 80–90 nM in response to the muscarinic agonist, carbachol. Shortening of the cells occurred 200 ms after intracellular calcium began to rise. The sensitivity and reliability of these methods allowed the effects of different stimuli to be easily resolved. The present report demonstrates that genuine contractility need not be ignored in cultured smooth muscle cells and that the temporal relations between shortening and intracellular calcium mobilization can be quantitatively assessed in controlled in vitro environments.

The small intestinal epithelium plays an important role in the mucosal host defense. Intestinal epithelial cells have been known to release substances that suppress lymphocyte proliferation, suggesting an immunoregulatory function. We investigated how intestinal epithelial cells affect lymphocyte proliferation. Serum-free medium that was conditioned by incubating epithelial cells, particularly crypt cells, of the rat small intestine affected proliferation of allogeneic spleen lymphocytes stimulated with concanavalin A, as assessed by measuring cellular [³H]thymidine incorporation. Less than 1% and greater than 2% of the conditioned medium enhanced and suppressed, respectively, lymphocyte proliferation. The causative substances found in the conditioned medium were dialyzable and heat-stable. Suppression was not due to toxicity to splenocytes. Exposure of splenocytes to a suppressive concentration of the conditioned medium beginning at 30 min before an onset of lectin stimulation decreased the suppression of lymphocyte proliferation. Splenocyte exposure to the suppressive concentration of the conditioned medium beginning at 30 min to 4 h after the onset of the stimulation inversely strengthened the suppression. A brief exposure of splenocytes to the conditioned medium for the last 4 h during a total 72-h culture period still suppressed lymphocyte proliferation. Thus, intestinal epithelial cells produce low-molecular-weight lymphocyte proliferation-modulating substances that suppress the proliferation of lectin-activated lymphocytes, but not resting ones, by affecting earlier intracellular events and the following DNA synthesis when incubated in culture medium.