p53 deficiency induces cancer stem cell pool expansion in a mouse model of triple-negative breast tumors.

Triple-negative breast cancer is a heterogeneous disease characterized by the expression of basal cell markers, no estrogen or progesterone receptor expression and a lack of HER2 overexpression. Triple-negative tumors often display activated Wnt/ß-catenin signaling and most have impaired p53 function. We studied the interplay between p53 loss and Wnt/ß-catenin signaling in stem cell function and tumorigenesis, by deleting p53 from the mammary epithelium of K5ΔNßcat mice displaying a constitutive activation of Wnt/ß-catenin signaling in basal cells. K5ΔNßcat transgenic mice present amplification of the basal stem cell pool and develop triple-negative mammary carcinomas. The loss of p53 in K5ΔNßcat mice led to an early expansion of mammary stem/progenitor cells and accelerated the formation of triple-negative tumors. In particular, p53-deficient tumors expressed high levels of integrins and extracellular matrix components and were enriched in cancer stem cells. They also overexpressed the tyrosine kinase receptor Met, a feature characteristic of human triple-negative breast tumors. The inhibition of Met kinase activity impaired tumorsphere formation, demonstrating the requirement of Met signaling for cancer stem cell growth in this model. Human basal-like breast cancers with predicted mutated p53 status had higher levels of MET expression than tumors with wild-type p53. These results connect p53 loss and ß-catenin activation to stem cell regulation and tumorigenesis in triple-negative cancer and highlight the role of Met signaling in maintaining cancer stem cell properties, revealing new cues for targeted therapies.

Challenges in the stratification of breast tumors for tailored therapies.

Studying the molecular stratification of breast carcinoma is a real challenge considering the extreme heterogeneity of these tumors. Many patients are now treated following recommendation established at several NIH and St Gallen consensus conferences. However a significant fraction of these breast cancer patients do not need adjuvant chemotherapies while other patients receive inefficacious therapies. High density gene expression arrays have been designed to attempt to establish expression profiles that could be used as prognostic indicators or as predictive markers for response to treatment. This review is intended to discuss the potential value of these new indicators, but also the current weaknesses of these new genomic and bioinformatic approaches. The combined analysis of transcriptomic and genomic alteration data from relatively large numbers of well annotated tumor specimens may offer an opportunity to overcome the current difficulties in validating recently published non overlapping gene lists as prognostic or therapeutic indicators. There is also hope for identifying and deciphering signal transduction pathways driving tumor progression with newly developed algorithms and semi quantitative parameters obtained in simplified in vitro or in vivo models for specific transduction pathways.

Growth defects induced by perturbation of beta1-integrin function in the mammary gland epithelium result from a lack of MAPK activation via the Shc and Akt pathways.

Adhesion to extracellular matrix (ECM) induces intracellular signals that modulate cell proliferation, survival and differentiation. To study signalling events triggered by cell-ECM interactions in vivo we used transgenic mice exhibiting reduced mammary epithelial cell proliferation and increased apoptosis rates during the growth phase in pregnancy and lactation due to expression of a beta1-integrin dominant-negative mutant in the mammary gland epithelium. Here we show that ERK and JNK MAPKs were markedly less activated in lactating transgenic glands thereby accounting for the growth defects. The FAK pathway was not affected suggesting a mechanism of activation additional to the ECM signal. On the contrary, the significant decrease of Shc phosphorylation, Grb2 recruitment and the reduced phosphorylation level of Akt Thr308 and Akt substrates FKHR and Bad detected in transgenic glands show that activation of the Shc and the Akt pathways require intact cell-ECM interactions. These results provide an insight into the mechanisms of growth control by integrin-mediated adhesion that operate in vivo.

Development of mammary gland requires normal beta 1-integrin function.

To study the role of beta 1-integrins in mammary gland development we have generated transgenic mice expressing a dominant negative mutant of the beta 1-integrin chain in the mammary epithelium. The transgenic glands presented a delayed development in pregnancy and lactation due to decreased epithelial cell proliferation and increased apoptosis, whereas at the beginning of lactation, expression of milk proteins, WAP and beta-casein was diminished. In correlation with transgene expression, the basement membrane component, laminin, and the beta 4 integrin were accumulated at the lateral surface of luminal epithelial cells, revealing defects in polarization. Our data show that beta 1-integrins are involved in vivo in the control of proliferation, apoptosis, differentiation, and maintenance of baso-apical polarity of mammary epithelium.

Cell-extracellular matrix interactions and EGF are important regulators of the basal mammary epithelial cell phenotype.

The mammary epithelium is composed of a luminal epithelium and a basal layer containing myoepithelial cells and undifferentiated precursors. Basal cells express specific protein markers, such as keratin 14 (K14) and P-cadherin. To study the factors that regulate the basal mammary epithelial cell phenotype, we have established two clonal derivatives of the mouse HC11 cell line, BC20 and BC44, expressing high levels of K14 and P-cadherin. Unlike the parental HC11 cells, these basal cells did not produce beta-casein in response to lactogenic hormone treatment; however their phenotype appeared to be plastic. Cultured in EGF-free medium, they exhibited enhanced cell-extracellular matrix adhesions and deficient cell-cell junctions, whereas long-term treatment with EGF induced a decrease of focal contact number and establishment of cell-cell junctions, resulting in downregulation of K14 and P-cadherin expression at the protein and mRNA levels. To determine whether cell-extracellular matrix interactions mediated by integrins have a role in the regulation of the expression of K14 and P-cadherin, the amounts of transcripts for the two proteins were analysed in the basal cells, which were plated on the function-blocking antibodies against beta1 and alpha6 integrin chains, on fibronectin and on laminin 5. The amount of P-cadherin transcript was 2- to 4-fold higher in cells plated on the function-blocking anti-integrin antibodies and on the extracellular matrix proteins, as compared to cells plated on poly-L-lysine, whereas the K14 transcript levels were not significantly modified in response to adhesion. The data demonstrate that integrin-mediated cell interaction with extracellular matrix is directly implicated in the control of P-cadherin expression, and that EGF and cell-extracellular matrix adhesion events are important regulators of the basal mammary epithelial cell phenotype.

Perturbation of beta1-integrin function alters the development of murine mammary gland.

The expression of a transgene coding for a chimeric molecule, containing the cytoplasmic and transmembrane domains of the beta1-integrin chain and the extracellular domain of the T-cell differentiation antigen CD4, was targeted to the mouse mammary gland by the mouse mammary tumor virus (MMTV) promoter. The chimera does not interact with the extracellular ligands; however, its expression in cultured cells was shown to interfere with focal adhesion kinase (FAK) phosphorylation following ligation of endogenous beta1-integrin. Therefore, expression of the transgenic protein on the cell surface should uncouple adhesion from intracellular events associated with the beta1-cytoplasmic domain and thus perturb beta1-integrin functions. Although most of the transgenic females were able to lactate, their mammary glands had a phenotype clearly distinct from that of wild-type mice. At mid-pregnancy and the beginning of lactation, transgenic glands were underdeveloped and the epithelial cell proliferation rates were decreased, while the apoptosis levels were higher than in wild-type glands. In lactation, the amounts of the whey acidic protein (WAP) and beta-casein gene transcripts were diminished, and the basement membrane component, laminin and the beta4-integrin chain accumulated at the lateral surface of luminal epithelial cells, revealing defects in polarization. Our observations prove that in vivo, beta1-integrins are involved in control of proliferation, apoptosis, differentiation and maintenance of baso-apical polarity of mammary epithelial cells, and therefore are essential for normal mammary gland development and function.

Myoepithelial cell differentiation in the developing mammary gland: progressive acquisition of smooth muscle phenotype.

The most important portion of the mammary gland development occurs postnatally, with distinct periods of intensive morphogenesis taking place between birth and puberty and during pregnancy and lactation. To characterize the differentiation process of mammary myoepithelial cells, we have studied the expression patterns of several smooth muscle phenotypic markers, including contractile proteins, alpha-smooth muscle-actin (alpha-SM-actin), smooth muscle myosin heavy chains (SM-MHC), and calponin; components of cell-extracellular matrix adherens junctions, phosphoglucomutase-related protein (PGM), vinculin variants, integrin subunits; and laminin variant chains in the developing rat mammary gland using immunofluorescence microscopy. alpha-SM-actin- and SM-MHC-positive cells were found first in newborn animals, while calponin, PGM and alpha1 integrin subunit began to be expressed in prepubertal animals (1.5 weeks). Vinculin, beta1 and alpha3 integrin subunits were largely confined to the basal cell layer at all developmental stages examined with greater staining starting at 1.5 weeks. Meta-vinculin was identified only in myoepithelial cells of the lactating gland. gamma1 laminin chain was present in the mammary gland basement membrane throughout development, while the beta2 chain was revealed in 3-week-old animals and accumulated later in postpubertal animals (7 weeks). Similarly, beta2 laminin chain was absent from the forming alveoli basement membrane in pregnant rats and started to accumulate in the lactating gland. In addition to temporal changes, we have observed spatial differences in the distribution of the phenotypic markers. Both in pre- and in postpubertal animals, alpha-SM-actin- and SM-MHC-positive cells of the growing ductal ends contained low amounts if any of calponin, PGM, and beta2 laminin chain. We conclude that during postnatal development, mammary myoepithelial cells progressively acquire a differentiated phenotype as revealed by the expression of various smooth muscle markers. Maturation of the myoepithelial cells is accompanied by upregulation of the smooth muscle integrin expression followed by accumulation of beta2-containing laminin variant. Thus, changes in adhesion system parallel with the myoepithelial cell differentiation.

Tumor progression: the role of cadherins and integrins.

Established cadherin and integrin-containing adherens junctions maintain the integrity of normal tissues. Signalling via adhesion-molecule systems is an important factor in the control of cellular growth and differentiation. In transformed cells, destructive changes in the adhesion systems lead to abnormal relationships among neighbouring cells and the extracellular matrix. Adhesion molecules may prevent tumour progression by firmly attaching cells to each other, and by anchoring them in the extracellular matrix. In addition, cadherins and integrins may have a direct role in tumour suppression by participating in growth control. Dissemination of cancer cells, i.e. invasion and metastasis, requires movement of cells, as well as adhesion to extracellular matrices and to other cells. Particular integrins have been implicated in several aspects of this multistep process. In this article, the data on the possible roles of cadherins and integrins in tumor progression are summarized.

CD34-positive early stages of human T-cell differentiation.

Thymus, the main organ for T lymphopoiesis, requires a permanent influx of progenitors from bone marrow (BM) or fetal liver. An essential question relating to early T-cell development is the identification of the progenitor population which actually homes to the thymus. Recent findings have shown that human multipotent progenitor/stem cells expressing CD34 have the capacity to differentiate into T cells when introduced into a thymic environment. More mature CD34+ bone marrow cells coexpressing CD7 and having a poor myeloid differentiation capacity can also efficiently differentiate into T cells in vitro. These lymphoid committed precursors might be the true thymic repopulating cells. In the thymus, cells with a similar CD34+7+ phenotype include the most primitive thymocyte precursors. CD34+ thymocytes have no myeloid differentiation potential, but may include precursors for natural killer (NK) cells. Interleukin-7 (IL7) is a potent in vitro growth factor for CD34+ thymocytes. Whereas current data do not support a crucial role for IL2, patients with IL2 receptor gamma chain (IL2R gamma) deficiency lack T- and NK cells. The recent demonstration that IL2R gamma is part of the receptor for IL7 strongly suggests that this cytokine plays an essential role in in vivo T lymphocyte and NK development.

Analysis of early reconstitution events in the SCID mouse thymus following rat bone marrow cell transplantation.

In this work, we provide comprehensive evidence that sublethally irradiated Thy-1.2 SCID mice can be used as a model system for thymus homing and reconstitution after intravenous transfer of rat bone marrow cells. Full short-term SCID mouse thymus reconstitutions were obtained using a plastic nonadherent low-density rat bone marrow cell subset. Cell counts and flow cytometric analysis showed that at 3 weeks post-transfer the SCID mouse thymus contained up to 41 x 10(6) Thy-1.1high rat lymphoid cells comprising the expected percentages and distribution of CD2+, CD5+, CD3+, alpha beta TCR+ and CD4+ CD8+ cells. As seen on cryostat sections, bone marrow-derived MHC class II+ accessory cells had already developed by 2 weeks post-transfer, preceding the thymocyte expansion apparent at 3 weeks. Thus, analysis of the early events of SCID thymus reconstitution by rat bone marrow cells shows that they closely resemble those described in congenic animals and points out the temporally distinct development of dendritic cells and thymocytes. The SCID mouse-rat chimera model system represents a new in vivo tool for manipulating rat T-cell differentiation from bone marrow-resident precursor cells and in addition supports our previous xenogeneic reconstitution studies performed in organ culture.

Enrichment and characterization of thymus-repopulating cells in stroma-dependent cultures of rat bone marrow.

The bone marrow precursor cells seeding the thymus have been difficult to investigate using fresh bone marrow and in vivo thymus reconstitution assays. We have therefore designed a short-term bone marrow culture system allowing the study of thymus-repopulating cells in the marrow microenvironment. Low-density rat bone marrow cells were grown on pre-established mouse bone marrow stromal cell layers. Cocultured cells were maintained either under steroid-free conditions (Whitlock/Witte-type culture) or in the presence of 10(-7) M hydrocortisone (Dexter-type culture). After 3 days in vitro, the unanchored cell fractions were tested for their ability to colonize and repopulate fetal mouse thymic lobes in vitro. Both fresh low-density cells and Whitlock/Witte-type cultures, but not Dexter-type cultures, gave rise intrathymically to significant numbers of rat donor-type Thy-1.1high CD2+ CD5low CD43+ cells accounting for 50% to 90% of the organ-cultured cells at day 14. Repopulation of fetal mouse thymic lobes by rat Thy-1.1high cells could be used as a readout assay for initiation of thymopoiesis from bone marrow precursor cells, since 90% of the cells were CD3-/low and TCR alpha beta-/low and 15% of the cells co-expressed CD4 and CD8. Dose-response analysis showed that thymus repopulating cells were at least maintained, if not amplified during the 3-day culture period, leading to at least a 10-fold enrichment as compared to unfractionated bone marrow. Unlike fresh low-density cells before culture, short-term Whitlock/Witte-type cultures were depleted in myeloid-restricted precursor cells. In culture, the thymus-repopulating activity was predominantly associated with a 10% lymphoid cell subset which did not express the B-lineage-associated antigens revealed by HIS24 (the rat B220 equivalent) and HIS50 mAbs. We propose that unanchored thymus-repopulating cells enriched in Whitlock/Witte-type cultures may represent lymphoid-restricted, T-cell precursors of the bone marrow capable of emigrating and colonizing the thymus.

Endogenous and exogenous alpha-fetoproteins as differential markers of cultured neonatal mouse Schwann cells and fibroblasts.

alpha-Fetoprotein (AFP) and AFP-gene transcripts were demonstrated in vitro in Schwann (S) cell and fibroblast (F) cell cultures of neonatal mouse origin. All S and F cells of primary cultures and of established cell lines expressed the AFP gene. AFP mRNA was detected by an in situ hybridization technique using a 35S-AFP-cDNA probe. AFP was localized by immunocytoperoxidase labelling using purified anti-AFP antibodies. The amounts of stained endogenous AFP, estimated semiquantitatively, were about 3-fold higher in S cells than in F cells. After incubating the cultures with exogenous mouse AFP, both S and F cells showed significant ability to take up the protein; the amount of internalized protein was found to be higher in F cells than in S cells. Moreover, the uptake of AFP fluorescein conjugates (FITC-AFP), estimated quantitatively by fluorometry, also gave higher values for F cells. The cytoplasm of F cells exhibited a characteristic fluorescence pattern, strongly illuminated and dispersed grains; the cytoplasm of S cells was regularly labelled. If exogenous FITC-AFP uptake could be used to distinguish labelled F cells from S cells (with application for identification and selection of F cells), the immunocytochemically stained endogenous AFP could allow S cells to be distinguished from F cells (using the dilutions of antibodies still staining the S cells but which lead to the absence of F-cell labelling). The two procedures, which can be used independently or together, may constitute differential markers for S cell and F cultures in, i.e., nerve regeneration of neurofibroma studies using the model of mixed S and F culture also containing other types of cells.

Overproduction and secretion of beta 2-microglobulin by a rat thymic epithelial cell line that expresses MHC class I heavy chain.

Major histocompatibility complex (MHC) class I antigens are constituted of dimers consisting of a peripheral light chain, beta 2-microglobulin (beta 2m) and a transmembrane heavy chain whose cell surface expression depends on its assembly with beta 2m. In contrast, soluble beta 2m can be secreted in the absence of heavy chain expression. The presence of beta 2m in medium conditioned by a rat thymic epithelial cell line, IT45-R1 (IT45) prompted us to investigate whether beta 2m could be secreted by cells that express MHC class I antigens. IT45 cells produce three to five times more beta 2m in the culture supernatant than another rat thymic epithelial cell line, IT26-R21 (IT26). The IT45 cell line exported beta 2m through a constitutive pathway of secretion, as indicated by the kinetics of production and localization of intracellular beta 2m. Although cells from the IT45 cell line expressed a much higher amount of beta 2m as compared to IT26 and NBT II cells (a rat bladder epithelial cell line), all three of these cell lines expressed the same amount of membrane and intracellular MHC class I heavy chain. These data are thus consistent with a constitutive secretion of beta 2m dependent upon an overexpression of MHC class I light chain as compared to the heavy chain. The amount of beta 2m mRNA and the ratio of beta 2m versus MHC class I heavy chain transcripts were higher in IT45 than in IT26 cells, indicating that overexpression of beta 2m in IT45 cells could be due to an enhanced level of beta 2m mRNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Rat bone marrow cells undergo thymopoiesis in mouse fetal thymic organ culture.

We have developed an in vitro differentiation assay allowing the study of thymopoiesis from rat bone marrow cells. In this assay, Wistar rat bone marrow cells repopulated fetal Swiss mouse thymic lobes depleted in endogeneous lymphoid cells by deoxyguanosine treatment. Due to the xenogeneic situation, repopulating rat cells from any hemopoietic lineage could be easily recognized by anti-rat monoclonal antibodies such as anti-Thy-1.1 that did not react with Swiss mouse thymocytes. After 15 days in vitro, 80% of the developing rat cells were Thy-1.1+ lymphoid cells and about 70% of the Thy-1.1+ cells expressed CD5, CD2 and leukosialin. The percentages of cells expressing pre-B cell, B cell and myeloid determinants were less than 20%. The developing thymocytes comprised CD4-CD8- T cell receptor (TcR) alpha/beta-, CD4-CD8+TcR alpha/beta low and CD4+CD8+TcR alpha/beta low cells, indicating that the early stages of rat thymopoiesis occurred within mouse thymic lobes. Limiting dilution assays showed that 50% of positive assays were obtained with 3000 nucleated bone marrow cells, which is in good agreement with recent estimates derived from in vivo reconstitution after intrathymical transfer. Moreover the limiting dilution assays proved to be sensitive enough to evidence a tenfold enrichment of pre-T cell activity in the low-density fraction of rat bone marrow. This xenogeneic system might greatly facilitate studies on prethymic and intrathymic stages of rat T cell development and permit new in vitro approaches of the colonizing bone marrow T cell precursor properties.

Thymotaxin, a chemotactic protein, is identical to beta 2-microglobulin.

Thymotaxin, an 11-kilodalton protein chemotactic for rat bone marrow hematopoietic precursors, was purified from media conditioned by a rat thymic epithelial cell line. The NH2-terminal sequence of thymotaxin was identical to that of rat beta 2-microglobulin (beta 2m). Antibodies to beta 2m removed thymotaxin activity from the fraction containing the 11-kilodalton protein. Chemotactic activity was observed with rat plasma beta 2m, human beta 2m, and mouse recombinant beta 2m, further supporting the identity of thymotaxin with beta 2m. The directional migration, as opposed to random movement, of the cells was also confirmed. The only rat bone marrow cells that migrated toward beta 2m were Thy1+ immature lymphoid cells devoid of T cell, B cell, and myeloid cell differentiation markers.

Characterization of rat T cell precursors sorted by chemotactic migration toward thymotaxin.

An established rat thymic cell line secretes a peptide in the 11 kd range called thymotaxin that attracts a small subset of juvenile rat bone marrow cells via a chemotactic mechanism. The selected cell subset (0.1% of the total bone marrow) is composed of low-density lymphoid cells that do not replicate, and display an immature Thy-1+T-B- phenotype. Thymotaxin-responding cells do not grow in semi-solid cultures under hemopoietic growth factors stimulation, and survive only in coculture with thymic stroma under steroid-free conditions. This stroma mimics the thymic microenvironment and allows a fraction of responding bone marrow cells to acquire T cell differentiation markers and to synthesize transcripts of the TCR alpha and beta chains. Chemotactic migration toward thymic epithelial cell peptides can be used in vitro to sort pre-T cells from the rat bone marrow. The sorted T cell precursors are resting stem cells possibly committed to lymphoid lineage.

Thymotaxin: a thymic epithelial peptide chemotactic for T-cell precursors.

The embryonic thymus is seeded by invading hemopoietic precursor cells that differentiate intrathymically into T lymphocytes. We have recently reported that avian thymic epithelial cells secrete chemotactic peptides, which provoke oriented migration of hemopoietic precursor cells in vitro. The established rat thymic epithelial cell line IT-45 R1 produced a polypeptide that resolves as a single band in the region of 11 kDa on NaDodSO4/polyacrylamide gels. This molecule, which we have named thymotaxin, induced a chemotactic response in a subpopulation of hemopoietic cells from juvenile rat bone marrow. Responding cells were generated by short-term coculture of rat bone marrow hemopoietic cells with mouse bone marrow stroma in a steroid-free medium. Cells selected in a chemotactic chamber have a lymphoid or blast cell morphology. The phenotype of the responding cells is Thy-1+, CD4- [corrected] and CD8-. In contrast, CD8 T-lymphocyte differentiation antigen was expressed after coculture with embryonic thymic monolayers, suggesting that the responding cells correspond to the precursors colonizing the thymus.

Aspects of haemopoietic cell dynamics: ontogeny and targeted migration.

In the developing avian and mammalian embryo, haemopoietic cells appear first in transient foci whose function is restricted to discrete periods of embryogenesis. These foci are essentially represented by the yolk sac, intraembryonic dispersed foci and the liver. Haemopoietic cells then repopulate the developing spleen, thymus and bone marrow, organs which persist and develop after birth. In the present review, we describe a number of possible mechanisms controlling specific adhesion, oriented migration and invasiveness of haemopoietic cells. One concerns the high specificity of the interactions of homing receptors on the surface of haemopoietic cells with determinants on vascular endothelium and/or thymic epithelium. A second is the importance of the presence of some macromolecules in the extracellular matrix, such as fibronectin, collagen, laminin and elastin. These components can interact with the haemopoietic cells (and/or induce chemotaxis) via the existence of specific receptors on the surface of the haemopoietic cells. Another mechanism is the activation of the haemopoietic cells through the interactions of cell-chemotactic factor, cell-extracellular matrix and/or cell-thymic epithelium. This activation can lead to: 1) the expression of new specific cell-surface receptors for the target foci; 2) the secretion of specific protease and glycosidase systems active upon the extracellular matrix; and 3) the differentiation of these cells in the thymus.