Molecular aspects of adipoepithelial transdifferentiation in mouse mammary gland.

The circular, reversible conversion of the mammary gland during pregnancy and involution is a paradigm of physiological tissue plasticity. The two most prominent cell types in mammary gland, adipocytes and epithelial cells, interact in an orchestrated way to coordinate this process. Previously, we showed that this conversion is at least partly achieved by reciprocal transdifferentiation between mammary adipocytes and lobulo-alveolar epithelial cells. Here, we aim to shed more light on the regulators of mammary transdifferentiation. Using immunohistochemistry with cell type-specific lipid droplet-coating markers (Perilipin1 and 2), we show that cells with an intermediate adipoepithelial phenotype exist during and after pregnancy. Nuclei of cells with similar transitional structural characteristics are highly positive for Elf5, a master regulator of alveologenesis. In cultured adipocytes, we could show that transient and stable ectopic expression of Elf5 induces expression of the milk component whey acidic protein, although the general adipocyte phenotype is not affected suggesting that additional pioneering factors are necessary. Furthermore, the lack of transdifferentiation of adipocytes during pregnancy after clearing of the epithelial compartment indicates that transdifferentiation signals must emanate from the epithelial part. To explore candidate genes potentially involved in the transdifferentiation process, we devised a high-throughput gene expression study to compare cleared mammary fat pads with developing, contralateral controls at several time points during pregnancy. Incorporation of bioinformatic predictions of secretory proteins provides new insights into possible paracrine signaling pathways and downstream transdifferentiation factors. We discuss a potential role for osteopontin (secreted phosphoprotein 1 [Spp1]) signaling through integrins to induce adipoepithelial transdifferentiation.

Increased density of inhibitory noradrenergic parenchymal nerve fibers in hypertrophic islets of Langerhans of obese mice.

BACKGROUND AND AIM: We sought to identify mechanisms of beta cell failure in genetically obese mice. Little is known about the role of pancreatic innervation in the progression of beta cell failure. In this work we studied adrenergic innervation, in view of its potent inhibitory effect on insulin secretion. We analyzed genetically obese ob/ob and db/db mice at different ages (6- and 15-week-old), corresponding to different compensatory stages in the course of beta cell dysfunction. 15 week-old HFD mice were also studied. METHODS AND RESULTS: All mice were characterized by measures of plasma glucose, insulin, and HOMA. After perfusion, pancreata were dissected and studied by light microscopy, electron microscopy, and morphometry. Insulin, Tyrosine Hydroxylase-positive fibers and cells and Neuropeptide Y-positive cells were scored by immunohistochemistry. Islets of obese mice showed increased noradrenergic fiber innervation, with significant increases of synaptoid structures contacting beta cells compared to controls. Noradrenergic innervation of the endocrine area in obese db/db mice tended to increase with age, as diabetes progressed. In ob/ob mice, we also detected an age-dependent trend toward increased noradrenergic innervation that, unlike in db/db mice, was unrelated to glucose levels. We also observed a progressive increase in Neuropeptide Y-immunoreactive elements localized to the islet core. CONCLUSIONS: Our data show increased numbers of sympathetic nerve fibers with a potential to convey inhibitory signals on insulin secretion in pancreatic islets of genetically obese animals, regardless of their diabetic state. The findings suggest an alternative interpretation of the pathogenesis of beta cell failure, as well as novel strategies to reverse abnormalities in insulin secretion.

Selection of CD271(+) cells and human AB serum allows a large expansion of mesenchymal stromal cells from human bone marrow.

BACKGROUND: Mesenchymal stromal cells (MSC) are promising candidates for cell therapy and tissue engineering and may be used to treat acute graft-versus-host disease (GvHD). However, major obstacles for their clinical use are the required cell dose and the biosafety and potential immunogenicity of fetal bovine serum (FBS), which is a crucial supplement of all media currently used for the culture of MSC. METHODS: In this study MSC were successfully expanded after selection of CD271 cells from human bone marrow (BM) mononuclear cells in medium supplemented with 10% pooled allogeneic human serum. RESULTS: We isolated MSC from 10 healthy donor BM by plastic adherence and immunomagnetic selection of the CD271(+) fraction and expanded MSC in medium supplemented with pooled human allogeneic serum and animal serum. We isolated a homogeneous multipotent population by CD271(+) selection with a proliferation rate that was higher than MSC isolated by plastic adherence, 6.8+/-1.57 compared with 2.07+/-1.40 logs. Similar to cells generated in animal serum medium, MSC from allogeneic human serum were positive for mesenchymal markers and negative for hematopoietic markers; moreover they expressed embryonic stem cell genes. A normal karyotype and differentiation capacity into adipogenic, osteogenic and chondrogenic lineages and neurosphere-like structures were preserved throughout long-term culture. DISCUSSION: Expansion of MSC is both feasible and large with a CD271-selected population in medium supplemented with 10% pooled allogeneic human serum, without loss of multipotent differentiation capacity or karyotype alterations.

Characterization and expansion of mesenchymal progenitor cells from first-trimester chorionic villi of human placenta.

BACKGROUND: Mesenchymal stromal cells (MSC) have been identified in a variety of fetal and adult tissues, including bone marrow (BM), fetal blood and liver. We report on the isolation, expansion and differentiation in vitro of MSC-like cells from chorionic villi (CV). METHODS: We evaluated 10 samples of CV collected at the first trimester (gestational age 11-13 weeks). We only used cells taken from back-up culture after a successful karyotype analysis. CV cells were characterized by morphologic, immunophenotypic and molecular analysis. The differentiation ability of mesenchymal and neural lineages was detected using specific culture conditions. Cell expansion was assessed after plating cells at different densities in different media, supplemented with animal and human serum. RESULTS: CV cells showed a homogeneous population of spindle-shaped cells after the first passage. Cells expressed CD90, CD105, CD73, CD44, CD29 and CD13 but not CD45, CD14, CD34 and CD117. They expressed Oct-4, Rex-1, GATA-4 and nestin, which characterize the undifferentiated stem cell state. They differentiated into osteocytes, adipocytes, chondrocytes and neuronal cells. Cell expansion was greater than that of adult BM-derived MSC, 9 logs with fetal bovine serum and 6 logs with human serum. Despite their high proliferative capacity, we did not observe any karyotypic abnormalities after culture. DISCUSSION: Our study shows that CV cells have better potential for expansion than adult stem cells. They can proliferate in a medium with human allogeneic serum and can differentiate into mesenchymal and neural lineages. CV cells may be an excellent cell source for therapeutic applications.