p53 restoration kills primitive leukemia cells in vivo and increases survival of leukemic mice

Loss of p53 function is a common feature of human cancers and it is required for differentiated tumor cell maintenance; however, it is not known whether sustained inactivation of the p53 pathway is needed for cancer stem cell persistence. Chronic myeloid leukemia (CML) is caused by a chromosome translocation that generates the BCRABL oncogene encoding a constitutively active protein tyrosine kinase. The disease originates in a hematopoietic stem cell and is maintained by leukemic stem cells (LSCs). Treatment with specific tyrosine kinase inhibitors does not eliminate LSCs because they do not depend on the oncogene for survival. We have combined a switchable p53 knock-in mouse model, p53^KI/KI, with the well-characterized Sca1-BCRABLp210 CML transgenic model, to show that transient restoration of p53 slows disease progression and significantly extends the survival of leukemic animals, being the mechanism responsible for this effect, apoptotic death of primitive leukemia cells. In agreement with these in vivo findings, in vitro assays show that restoring p53 reduces hematopoietic colony formation by cells of leukemic animals. These results suggest that reestablishing p53 function may be a therapeutic strategy for the eradication of leukemic stem cells and to prevent disease progression.     

Rapid proliferation of daughter cells lacking particular chromosomes due to multipolar mitosis promotes clonal evolution in colorectal cancer cells

Aneuploidy and chromosome instability (CIN) are hallmarks of the vast majority of solid tumors. However, the origins of aneuploid cells are unknown. The aim of this study is to improve our understanding of how aneuploidy and/or CIN arise and of karyotype evolution in cancer cells. By using fluorescence in situ hybridization (FISH) on cells after long-term live cell imaging, we demonstrated that most (> 90%) of the newly generated aneuploid cells resulted from multipolar divisions. Multipolar division occurred in mononucleated and binucleated parental cells, resulting in variation of chromosome compositions in daughter cells. These karyotypes can have the same chromosome number as their mother clone or lack a copy of certain chromosomes. Interestingly, daughter cells that lost a chromosome were observed to survive and form clones with shorter cell cycle duration. In our model of cancer cell evolution, the rapid proliferation of daughter cells from multipolar mitosis promotes colonal evolution in colorectal cancer cells.     

The mysterious human epidermal cell cycle,or an oncogene-induced differentiation checkpoint

Fifteen years ago, we reported that proto-oncogene MYC promoted differentiation of human epidermal stem cells, a finding that was surprising to the MYC and the skin research communities. MYC was one of the first human oncogenes identified, and it had been strongly associated with proliferation. However, it was later shown that MYC could induce apoptosis under low survival conditions. Currently, the notion that MYC promotes epidermal differentiation is widely accepted, but the cell cycle mechanisms that elicit this function remain unresolved. We have recently reported that keratinocytes respond to cell cycle deregulation and DNA damage by triggering terminal differentiation. This mechanism might constitute a homeostatic protection face to cell cycle insults. Here, I discuss recent and not-so-recent evidence suggesting the existence of a largely unexplored oncogene-induced differentiation response (OID) analogous to oncogene-induced apoptosis (OIA) or senescence (OIS). In addition, I propose a model for the role of the cell cycle in skin homeostasis maintenance and for the dual role of MYC in differentiation.     

Fusion of GFP to the Carboxyl Terminus of Connexin43 Increases Gap Junction Size in HeLa Cells

The pattern of gap junctional coupling between cells is thought to be important for the proper function of many types of tissues. At present, little is known about the molecular mechanisms that control the size and distribution of gap junctions. We addressed this issue by expressing connexin43 (Cx43) constructs in HeLa cells, a connexin-deficient cell line. HeLa cells expressing exogenously introduced wild-type Cx43 formed small, punctate gap junctions. By contrast, cells expressing Cx43-GFP formed large, sheet-like gap junctions. These results suggest that the GFP tag, which is fused to the carboxyl terminus of Cx43, alters gap junction size by masking the carboxyl terminal amino acids of Cx43 that comprise a zonula occludins-1 (ZO-1) binding site. We are currently testing this hypothesis using deletion and dominant-negative constructs that directly target the interaction between Cx43 and ZO-1.     

Characterization of Morphological and Cytoskeletal Changes in MCF10A Breast Epithelial Cells Plated on Laminin-5: Comparison with Breast Cancer Cell Line MCF7

The extracellular matrix regulates functional and morphological differentiation of mammary epithelial cells both in vivo and in culture. The MCF10A human breast epithelial cell line is ideal for studying these processes because it retains many characteristics of normal breast epithelium. We describe a distinct set of morphological changes occurring in MCF10A cells plated on laminin-5, a component of the breast gland basement membrane extracellular matrix. MCF10A cells adhere and spread on laminin-5 about five times more rapidly than on fibronectin or uncoated surfaces. Within 10 minutes from plating on laminin-5, they send out microfilament-rich filopodia and by 30 minutes acquire a cobblestone appearance with microfilaments distributed around the cell periphery. At 90 minutes, with or without serum, >75% of the MCF10A cells plated on laminin-5 remain in this stationary cobblestone phenotype, while the remainder takes on a motile appearance. Even after 18 hours, when the culture is likely entering an exponential growth phase, the majority of cells maintain a stationary cobblestone appearance, though motile cells have proportionally increased. In contrast, the fully transformed, malignant human breast epithelial cells, MCF7, never acquire a stationary cobblestone appearance, do not organize peripheral microfilaments, and throughout the early time points up to 120 min appear to be constantly motile on laminin-5. We propose that changes in morphology and microfilament organization in response to laminin-5 may represent a benchmark for distinguishing normal vs. malignant behavior of epithelial cells derived from the mammary gland. This may lead to better model systems for studying the interactions between breast epithelium and the basement membrane extracellular matrix, which appear to be deregulated in processes like carcinogenesis and metastasis.     

Plakophilin-2 and the migration,differentiation and transformation of cells derived from the epicardium of neonatal rat hearts

Abstract

During development, epicardial cells act as progenitors for a large fraction of non-myocyte cardiac cells. Expression and function of molecules of the desmosome in the postnatal epicardium has not been studied. The objective of this study was to assess the expression of desmosomal molecules, and the functional importance of the desmosomal protein plakophilin-2 (PKP2), in epicardial and epicardium-derived cells. Epicardial explants were obtained from neonatal rat hearts. Presence of mechanical junction proteins was assessed by immunocytochemistry. Explants after PKP2 knockdown showed increased abundance of alpha smooth muscle actin-positive cells, increased abundance of lipid markers, enhanced cell migration velocity and increased abundance of a marker of cell proliferation. We conclude that a population of non-excitable, cardiac-resident cells express desmosomal molecules and, in vitro, show functional properties (including lipid accumulation) that depend on PKP2 expression. The possible relevance of our data to the pathophysiology of arrhythmogenic right ventricular cardiomyopathy, is discussed.     

Distribution of αvβT3, αvβTB5 Integrins and the Integrin Associated Protein — IAP (CD47) in Human Glomerular Diseases

The av integrins present on the membrane of numerous cells, mediate attachment to matrix proteins, cell proliferation, migration and survival. We studied the expression of av integrins and CD47 (a 03 chain integrin associated protein) in various forms of glomerulonephritis (GN) characterized by mesangial proliferation and/or increased mesangial matrix. In normal glomeruli, epithelial cells expressed αvβT3, αvβT5 and CD47; endothelial cells expressed α5βT1 and CD47; mesangial cells expressed αvβT5, CD47, and to a less extent αvβT3. In acute post infectious GN (APIGN), membranoproliferative GN (MPGN) and diabetic nephropathy (DN), we observed that the βT3 chain, normally expressed by mesangial cells, was not detectable in the mesangium while its expression by epithelial cells was not modified. Parallel to the disappearance of αvβT3, the CD47 expression was decreased on the mesangial cells in MPGN, APIGN and DN. The expression of αvβT5 was clearly increased on podocytes and on proliferating mesangial cells in APIGN. By contrast, the mesangial expression of αvβT5 normal or decreased in DN. The α5 chain of integrin, absent on normal mesangial cell, was expressed on proliferating mesangial cells in MPGN and APIGN.

Thus, we observed modifications of avp3 and avp5 expression during human GN. The modulations of αvβT3 and αvβT5 expression differed according to the different glomerular cell types and were not parallel in glomerular cells: avp3 was decreased (and αvβT5 unchanged) on proliferating mesangial cells and αvβT5 was increased (and αvβT3 unchanged) in podocytes. This may reflect the existence of two distinct regulatory pathways.     

INTERFERENTIAL ELECTRIC FIELDS REVEAL NONUNIFORM EFFECTS ON PROLIFERATION AND hCG SECRETION IN JAr CELLS

The effect of low frequency electromagnetic fields on changes in intracellular cAMP concentrations was investigated in the frequency range 10–100 Hz using a choriocarcinoma cell line. JAr cells significantly reduce proliferation and increase β-hCG secretion upon dibutyryl cAMP and forskolin treatment after 10 days of culturing. Choriocarcinoma cells exposed to a modulation frequency of 10 Hz for 5 min change their intracellular cAMP level significantly to higher as well as to lower concentrations in half of the experimental series, respectively. At frequencies of 70 and 100 Hz levels, half of the experimental series revealed a significant decrease in cAMP levels. Long term exposure at 100 Hz for 10 days leads to a significant reduction in proliferation but not in β-hCG secretion. These results point to a modulatory effect of low frequency electromagnetic fields on intracellular cAMP levels which are dependent on the frequency window. The reduced proliferation after long term exposure at the frequency of 100 Hz, which lowers cAMP levels, is discussed.     

Endothelial cells of adipose tissues: A niche of adipogenesis

Comment on: Tran KV, et al. Cell Metab 2012; 15:222-9.