Cystlike structures derived from the marginal cells of Rathke's cleft in rat pituitary grafts

Activated phenotype of the pituitary stem/progenitor cell compartment during the early-postnatal maturation phase of the gland

The rodent pituitary gland undergoes prominent maturation during the first weeks after birth, including a well-known increase in hormone-producing cells. In the past, it has frequently been postulated that stem cells are involved in this early-postnatal growth phase. This hypothesis can now be explored, as pituitary stem/progenitor cells were recently identified. Here, we analyzed in detail the mouse pituitary stem/progenitor cell compartment during the first postnatal week and compared its phenotype with that at the end of the first pituitary growth wave and at adult age. Stem/progenitor cells, as assessed by both side population phenotype and Sox2 expression, are most abundant at birth and gradually decline toward adulthood. The neonatal stem/progenitor cell compartment is clearly more active in terms of proliferation, stemness gene expression, and stem cell-related functional activity including sphere formation and multipotent differentiation capacity. In situ examination of pituitary sections reveals peculiar topographical arrangements of Sox2+ cells, again more pronounced at the neonatal age. Sox2+ cells are particularly prominent at the wedge junction of the anterior and intermediate lobe, and clusters of Sox2+ cells appear to sprout from this and other cleft-lining, marginal zone regions. Colocalization of Sox2 and hormones is generally not observed, thus suggesting mutually exclusive expression. Together, the neonatal pituitary stem/progenitor cell compartment displays an activated phenotype, thus supporting its involvement in the early-postnatal maturation process of the gland.

Non-hormonal cell types in the pituitary candidating for stem cell

Hormone balances in the body are primarily governed by the hypothalamus-pituitary system. For its pivotal role, the pituitary gland relies on an assortment of different hormone-producing cell types, the proportions of which dynamically change in response to fluctuating endocrine demands. Mechanisms of pituitary cellular plasticity are at present far from understood, and may include proliferation and transdifferentiation of hormonal cells. Whether new cells also originate by recruitment from stem cells is unsettled, although this idea has frequently been proposed. Here, I will review these data by focusing on the non-hormonal cell types that have been advanced as candidates for the pituitary stem cell position.

Stem cells in the postnatal pituitary?

Tissue-specific stem cells are uncovered in a growing number of organs by their molecular expression profile and their potential for self-renewal, multipotent differentiation and tissue regeneration. Whether the pituitary gland also contains a pool of versatile 'master' cells that drive homeostatic, plastic and regenerative cell ontogenesis is at present unknown. Here, I will give an overview of data that may lend support to the existence of stem cells in the postnatal pituitary. During the many decades of pituitary research, various approaches have been used to hunt for the pituitary stem cells. Transplantation and regeneration studies advanced chromophobes as possible source of new hormonal cells. Clonogenicity approaches identified pituitary cells that clonally expand to floating spheres, or to colonies in adherent cell cultures. Behavioural characteristics and changes of marginal, follicular and folliculostellate cells during defined developmental and (patho-)physiological conditions have been interpreted as indicative of a stem cell role. Expression of potential stem cell markers like nestin, as well as topographical localization in the marginal zone around the cleft has also been considered to designate pituitary stem cells. Finally, a 'side population' was recently identified in the postnatal pituitary which in many other tissues represents a stem cell-enriched fraction. Taken together, in the course of the long-standing study of the pituitary, several arguments have been presented to support the existence of stem cells, and multiple cell types have been placed in the spotlight as possible candidates. However, none of these cells has until now unequivocally been shown to meet all quintessential characteristics of stem cells.

Nestin-immunoreactive cells in rat pituitary are neither hormonal nor typical folliculo-stellate cells

Nestin is an intermediate filament protein that has originally been identified as a marker of neuroepithelial stem/progenitor cells. The present study explored whether nestin immunoreactivity (nestin-ir) is present in the rat pituitary and in which cell type(s). Nestin-ir was observed in scattered cells in the anterior, intermediate, and neural lobes. Nestin-ir cells were predominantly of stellate shape and were more numerous in immature than in adult animals. Nestin-ir did not colocalize with any pituitary hormone, and did not colocalize or only very sporadically with the folliculo-stellate cell marker S100. In the intermediate lobe, nestin-ir cells contained glial fibrillary acidic protein in an age-dependent manner. Nestin-ir cells were closely associated with endothelial and fibronectin-ir cells, but did mostly not coincide. Nestin-ir was not found in alpha-smooth muscle actin-ir myofibroblasts or in microglial cells. Regardless of age, nestin-ir was detected in some unidentifiable cells that border the pituitary cleft. Nestin-ir remained present in pituitary cultured as three-dimensional aggregates. Treatment with basic fibroblast growth factor or leukemia inhibitory factor increased the number of nestin-ir cells. Starting from anterior lobe cell monolayer cultures, nestin-ir cells could be selected and propagated to a virtually pure population. These nestin-ir cells displayed remarkable motility and proliferative activity, and did not express hormones, glial fibrillary acidic protein, or S100, but contained vimentin-, fibronectin-, and alpha-smooth muscle actin-ir. In conclusion, nestin-ir is present in the pituitary in cells that are neither hormonal nor typical folliculo-stellate. The expression pattern depends on age and lobe examined. Pericapillar localization suggests a pericyte phenotype for some of them. Whether the heterogeneous nestin-ir population also contains pituitary progenitor cells remains to be explored.

Two distinct pituitary cell lines from mouse intermediate lobe tumors: a cell that produces prolactin-regulating factor and a melanotroph [seecomments]

The intermediate lobe (IL) of the pituitary produces a PRL-regulating factor (PRF). Targeted tumorigenesis, using the POMC promoter ligated to SV40 large T antigen (Tag), generated transgenic mice that develop IL tumors with PRF activity. Our goal was to establish and characterize a PRF-producing cell line. Two cell lines, which differ markedly in size and morphology, were independently developed from IL tumors and designated mIL5 and mIL39. These cells are transformed, as judged by rapid proliferation, low serum requirements, and generation of secondary tumors in nude mice. RT-PCR revealed that mIL39, but not mIL5 cells, express POMC and dopamine D2 receptors, typical of a melanotroph phenotype. Although mIL5 cells originated from an IL tumor, they do not express messenger RNA for SV40 Tag. The bioassay for PRF used GH3 cells stably transfected with the PRL promoter ligated to a luciferase reporter gene (GH3/luc). Coculture of mIL5 with GH3/luc cells induced cell-density dependent increases in PRL gene expression and release, whereas mIL39 cells showed negligible PRF activity. Incubation of GH3/luc cells with conditioned media from mIL5, but not mIL39 cells, stimulated PRL gene expression and release up to 10-fold. Coculture of mIL5 cells with primary rat anterior pituitary cells stimulated PRL, but not GH, release. Fractionation of mIL5 cell extracts by reverse phase HPLC resolved PRF activity into one major and one minor peak. In conclusion, we have developed two novel and distinct cell lines from mouse intermediate lobe tumors. The first reported melanotroph cell line, mIL39, could provide a valuable model for studying dopaminergic regulation of POMC gene expression and release. In contrast, the mIL5 cells do not express POMC, D2 receptors, or SV40 Tag and appear to have been immortalized by a spontaneous mutation(s). These cells produce and secrete a potent PRF and could be used for the purification and biochemical characterization of PRF.

Proliferative activity of cells of the intermediate lobe of the rat pituitary during the postnatal period

Cellular proliferation was studied in the intermediate lobe (IL) of the pituitary gland of developing rats by labelling cells at the S-phase of the cell cycle with bromodeoxyuridine (BrdU). The number of BrdU-labelled cells in the IL decreased from birth until the 14th postnatal day and was low from that day until the end of the first month after birth. Throughout the postnatal period a large proportion of BrdU-labelled cells was found in the marginal layer (ML) of the IL, suggesting for the ML a role as a germinative layer of the IL during postnatal growth. Double immunostaining with anti-BrdU and anti-MSH showed that MSH cells actively proliferate as from the day of birth. Cells doubly immunostained with anti-BrdU and anti-S100 protein were first seen on the 14th postnatal day. From then onwards, most proliferating cells were labelled with either anti MSH or anti S-100 protein. This, together with the high proportion of proliferating cells found in the ML marks a clear difference with the pattern of cellular proliferation previously reported during a similar period in the anterior lobe of the rat pituitary.

Characterization of the follicles in the intermediate lobe of the pituitary gland of the Mongolian gerbil (Meriones unguiculatus)

The Mongolian gerbil (Meriones unguiculatus) contains abundant follicles throughout the intermediate lobe (IL) of the pituitary gland in the adult animal. The mode of follicle formation, the nature of the follicle building cells and the distribution of follicles were investigated in semithin sections of the gerbil IL. The sections were stained conventionally, or immunohistochemically with antibodies directed against alpha-melanocyte stimulating hormone (alpha-MSH). Follicular cells were constantly alpha-MSH-negative, and resembled the marginal cells lining the hypophyseal cleft with regard to their cytological and immunohistochemical properties. Moreover, follicular cells appeared to be derived from strands of marginal cells that regularly invaginated deep into the IL. Both follicular and marginal cells often made up cellular clusters. This process coincided with follicle formation and the generation or transport of the colloidal content found inside follicles and the hypophyseal cleft. Although the non-secretory cells of the IL obviously constituted one major source of pituitary colloid in the gerbil, alpha-MSH-positive secretory cells, which occasionally were found to be discharged into the cleft cavity, might contribute to the colloidal contents.

Dome formation of keratin-containing agranular cells from rat anterior pituitary gland in vitro

A certain kind of cell in the pituitary gland exhibited immunoreactive keratin and dome formations in vitro. We obtained epithelial cells, which were able to subculture, from the outgrowth of anterior pituitary organ cultures. These cells lacked hormone secretory granules and exhibited immunoreactive keratin. Furthermore, they produced dome formations or cystic structures in monolayer culture and under three-dimensional culture condition using type I collagen gel. Dome formation was stimulated by dibutyryl cyclic AMP (dbcAMP, 10(-3) to 10(-5) M). Their responsiveness to dbcAMP is similar to that of several other epithelial cells that possess transport functions in vivo and in vitro. Although the origin of our cultured cells is unknown, these cells formed dome formations that possessed transport function and were related to cystic structures in the pituitary gland in vivo.

Granular, ciliated cells in the anterior pituitaries of immature rats

In this communication we demonstrate a new type of ciliated cell in the pituitary gland of immature rats. Anterior pituitary glands of rats, 31 days of age, were examined by electron microscopy. Around the agranular cells, which lined small cavities, there were sparsely granulated cells with many cilia (granular, ciliated cells). Their small granules, which were distributed along the cell membrane, had limiting membranes. Their cilia were of 9+2 type with a central pair of microtubules. It was suggested that the granular, ciliated cells might be an intermediate-type of cell for the different types of pituitary cells, which appear temporarily during pituitary ontogenesis.