Mesenchymal stem cells in mammary adipose tissue stimulate progression of breast cancer resembling the basal-type.

Data are accumulating to support a role for adipose-derived mesenchymal stem cells (MSCs) in breast cancer progression; however, to date most studies have relied on adipose MSCs from non-breast sources. There is a particular need to investigate the role of adipose MSCs in the pathogenesis of basal-like breast cancer, which develops at a disproportionate rate in pre-menopausal African-American women with a gain in adiposity. The aim of this study was to better understand how breast adipose MSCs (bMSCs) contribute to the progression of basal-like breast cancers by relying on isogenic HMT-3255 S3 (pre-invasive) and T4-2 (invasive) human cells that upon transplantation into nude mice resemble this tumor subtype.

Defining essential stem cell characteristics in adipose-derived stromal cells extracted from distinct anatomical sites.

The discovery of adipose-derived stromal cells (ASCs) has created many opportunities for the development of patient-specific cell-based replacement therapies. We have isolated multiple cell strains of ASCs from various anatomical sites (abdomen, arms/legs, breast, buttocks), indicating widespread distribution of ASCs throughout the body. Unfortunately, there exists a general lack of agreement in the literature as to their "stem cell" characteristics.

Electrospinning adipose tissue-derived extracellular matrix for adipose stem cell culture.

Basement membrane-rich extracellular matrices, particularly murine sarcoma-derived Matrigel, play important roles in regenerative medicine research, exhibiting marked cellular responses in vitro and in vivo, although with limited clinical applications. We find that a human-derived matrix from lipoaspirate fat, a tissue rich in basement membrane components, can be fabricated by electrospinning and used to support cell culture. We describe practical applications and purification of extracellular matrix (ECM) from adipose tissue (At-ECM) and its use in electrospinning scaffolds and adipose stem cell (ASC) culture.

Multipotent adipose stromal cells and breast cancer development: Think globally, act locally.

It has long been appreciated that stromal cells within the breast tumor microenvironment contribute to mammary carcinogenesis. However, to date, very little is known regarding the role of local adipose-derived stromal cells (ASCs) in the development of breast cancer. Based on pathological, epidemiological and experimental data, we postulate that breast-derived ASCs are unique mesenchymal stem-like cells that play a critical role in the development of breast cancer and discuss the global implications of this working model in terms of breast cancer prevention, early detection, and new targeted therapies.

Wilms' tumor 1 silencing decreases the viability and chemoresistance of glioblastoma cells in vitro: a potential role for IGF-1R de-repression.

Wilms' tumor 1 (WT1) is a transcription factor with a multitude of downstream targets that have wide-ranging effects in non-glioma cell lines. Though its expression in glioblastomas is now well-documented, the role of WT1 in these tumors remains poorly defined. We hypothesized that WT1 functions as an oncogene to enhance glioblastoma viability and chemoresistance.

Elevated TRF2 in advanced breast cancers with short telomeres.

Telomere repeat binding factor 2 (TRF2) binds directly to telomeres and preserves the structural integrity of chromosome ends. In vitro models suggest that expression of TRF2 protein increases during mammary cancer progression. However, a recent study has reported that TRF2 mRNA levels tend to be lower in clinical specimens of malignant breast tissue.

Isolating adipose-derived mesenchymal stem cells from lipoaspirate blood and saline fraction.

Isolation of adipose-derived stem cells (ASCs) typically involves 8+ hours of intense effort, requiring specialized equipment and reagents. Here, we present an improved technique for isolating viable populations of mesenchymal stem cells from lipoaspirate saline fractions within 30 minutes. Importantly, the cells exhibit remarkable similarities to those obtained using the traditional isolation protocols, in terms of their multipotent differentiation potential and immunophenotype.

CD4+ T cells inhibit the neu-specific CD8+ T-cell exhaustion during the priming phase of immune responses against breast cancer.

Studies conducted in animal model of infectious diseases or H-Y antigen model suggest a crucial role for CD4+ T cells in providing help for CD8+ T-cell memory responses. This concept suggests that inclusion of T helper epitopes in vaccine formulation will result in improved CD8+ T-cell responses. Although this concept has been applied to cancer vaccine design, the role of CD4+ T cells in the memory differentiation of CD8+ T cells and retention of their anti-tumor function have never been tested in breast cancer model.

Mechanism of dominant-negative telomerase function.

Human telomerase uses its integral core components, hTR and hTERT, to maintain telomeres in many cell types. Expression of a dominant-negative mutant of the catalytic subunit of telomerase, DN-hTERT, has been shown to cause telomere shortening and ultimately cell death in a number of tumor-derived cell lines. However, the mechanism of dominant-negative hTERT function and its fate inside the cell are still unknown.

Elevated expression of nuclear Hsp90 in invasive breast tumors.

With the current trend for early breast cancer detection, there is also a growing demand for discovering markers to assist in the patient risk stratification. Molecular chaperones play essential roles in the post-translational maturation of oncogenic client proteins and are strongly associated with carcinogenesis. To better define the role of chaperones in breast cancer, tissue arrays were immunostained for the chaperones Hsp90 and p23 and assessed in terms of reactivity, intensity and cellular localization.

Genetic inhibition of telomerase results in sensitization and recovery of breast tumor cells.

Telomerase, a ribonucleoprotein enzyme minimally composed of an RNA template (human telomerase RNA) and a catalytically active protein subunit (human telomerase reverse transcriptase), synthesizes telomeric repeats onto chromosome ends and is obligatory for continuous tumor cell proliferation. Telomerase is an attractive anticancer therapeutic target because its activity is present in >90% of human cancers, including >95% of breast carcinomas. Traditional chemotherapies lack the ability to effectively control and cure breast cancer, in part because residual cells are often resistant to DNA-damaging modalities.

Japanese medaka: a new vertebrate model for studying telomere and telomerase biology.

A good understanding of telomeres and telomerase biology is crucial for unraveling mechanisms related to aging and cancer. However, in vivo vertebrate studies of telomere biogenesis and telomerase function have been limited by the development of appropriate animal model systems. The present study aims to demonstrate evolutionary conservation of telomerase in vertebrate species, supporting the potential application of fish as vertebrate model for studying telomeres and telomerase function.

Overexpression of telomerase-associated chaperone proteins in prostatic intraepithelial neoplasia and carcinomas.

Over 90% of prostate cancers express telomerase activity. In an experimental model, hsp90 and p23, which are necessary for telomerase assembly and function, dramatically increase during tumorigenic conversion. We immunohistochemically analyzed 60 prostate carcinomas, 50 prostatic intraepithelial neoplasias (PIN) and 25 benign prostatic tissues to determine whether hsp90/p23 expression correlates with advancing stage and whether chaperone distribution overlaps with hTERT, the catalytic component of telomerase.

Accelerated senescence: an emerging role in tumor cell response to chemotherapy and radiation.

Treatment of malignancies with chemotherapeutic drugs and/or radiotherapy is designed to eliminate the disease by depriving the tumor cell of its reproductive potential. Frequently, the desired effect of cell killing is achieved through the promotion of apoptosis; however, accumulating evidence suggests that apoptosis may not be the exclusive or even primary mechanism whereby tumor cells lose their self-renewal capacity after radiation or drug treatment, particularly in the case of solid tumors. While failure to undergo apoptosis in response to chemotherapeutic drugs or radiation may represent a mechanism of drug and radiation resistance, particularly in the case of leukemias and lymphomas, it is gradually being recognized that in the case of solid tumors, loss of reproductive capacity can occur through alternative pathways including reproductive cell death or mitotic catastrophe, through autophagic cell death, and as described below, through a terminally arrested state similar to replicative senescence.

Recovery from stress is a function of age and telomere length.

Cells are constantly exposed to a wide variety of stimuli and must be able to mount appropriate physiological responses in order to maintain proper form and function. Cells from every organism have evolved highly conserved mechanisms to cope with environmental changes, including the widely studied heat shock response (HSR), which is induced by a variety of cellular stresses such as heavy metal ion exposure. It has long been known that as organisms and individual cells age, their ability to appropriately cope with environmental stress is attenuated.

Upregulation of telomerase function during tissue regeneration.

Telomerase plays a primary role in the maintenance of telomeres in immortal, germ, and tumor cells in humans but is lacking in most somatic cells and tissues. However, many species, including fish and inbred mice, express telomerase in most cells and tissues. Little is known about the expression of telomerase in aquatic species, although the importance of telomerase for longevity has been suggested.

Initiation of a zebrafish blastula cell line on rainbow trout stromal cells and subsequent development under feeder-free conditions into a cell line, ZEB2J.

A continuous cell line, ZEB2, was developed from zebrafish blastula-stage embryos expressing enhanced green fluorescent protein (GFP). Originally the rainbow trout spleen cell line, RTS34st, was used as feeders to initiate and maintain the cells through several passages. ZEB2 was then grown for 2 years without feeders in L-15 with 15% fetal bovine serum (FBS) for 120 population doublings.

A chemotherapy-associated senescence bystander effect in breast cancer cells.

A bystander effect typically refers to the death, altered growth or damage of cells that have not directly received chemotherapy or irradiation. Cancer cells derived from solid tumors readily undergo senescence in response to chemotherapeutic agents, prompting us to test for the existence of a senescence bystander effect. MCF-7 breast cancer cells were acutely exposed to Adriamycin to trigger senescence.

Vertebrate marine species as model systems for studying telomeres and telomerase.

Due to the limitations of in vitro human tissue culture systems, it has long been recognized that in vivo model organisms are critically necessary for studying important biological processes related to human disease. Telomere shortening and dysfunction have been shown as a contributing factor in aging using tissue culture systems and after 6 generations in inbred strains of mice. Currently, there are no models and little or no data defining the role of telomeres and telomerase in toxicological response, metal-induced carcinogenesis, or aging in marine animals.

Ectopic telomerase expression inhibits neuronal differentiation of NT2 neural progenitor cells.

There is significant interest in the potential use of telomerase-immortalized cells in transplantation to replace neurons lost to neurodegenerative diseases and other central nervous system injuries. Neural progenitor cells (NPCs) transduced with human telomerase reverse transcriptase (hTERT), the catalytic component of telomerase, have the potential both to proliferate indefinitely in vitro and to respond to differentiation signals necessary for generating appropriate cells for transplantation. The purpose of this study was to evaluate the differentiation of neurons from NT2 cells, a model NPC cell line, following hTERT transduction.

Telomerase inhibition as an adjuvant anticancer therapy: it is more than just a waiting game.

A telomere maintenance mechanism is essential for cancer cells to divide indefinitely. As telomerase maintains telomeres in the vast majority of human cancers, targeting tumor cells in patients with antitelomerase-based strategies is very appealing. However, as the complexities of telomere dynamics and telomerase regulation and function continue to unfold, translating this knowledge into well-designed clinical trials becomes daunting.

A cell line (HEW) from embryos of haddock (Melanogrammus aeglefinius) and its capacity to tolerate environmental extremes.

Cell lines can be useful experimental tools for studying marine fish, which are often difficult to routinely obtain and maintain in the laboratory. As few cell lines are available from coldwater marine fish, cultures were initiated from late gastrula embryos of haddock (Melanogrammus aeglefinus) in Leibovitz's L-15 with fetal bovine serum (FBS). From one culture, a cell line (HEW) emerged that has been grown for close to 100 population doublings, was heteroploid, and expressed telomerase activity, all of which suggest HEW is immortal.

Induction of nitric oxide synthase-dependent telomere shortening after functional inhibition of Hsp90 in human tumor cells.

In most cancer cells, the lengths of telomeres, the functional DNA-protein complexes located at chromosome ends, are maintained by the ribonucleoprotein telomerase. Hsp90 facilitates the assembly of telomerase and remains associated with the functional complex, implying a direct involvement of Hsp90 in telomere length regulation. In an effort to elucidate the effects of Hsp90 inhibition on function and viability of human prostate cancer cells, both pharmacological (radicicol) and genetic (small interfering RNA) approaches were utilized to target Hsp90.

erbB-2/neu transformed rat cholangiocytes recapitulate key cellular and molecular features of human bile duct cancer.

Background & Aims: Cholangiocarcinomas appear to arise from the malignant transformation of cholangiocytes lining the biliary tract. Because the development of an in vitro model of malignant transformation can provide a powerful new tool for establishing critical events governing the molecular pathogenesis of cholangiocarcinoma, we investigated the potential of achieving malignant transformation of cultured rat cholangiocytes in relation to aberrant overexpression of mutationally activated erbB-2/neu.

Methods: Malignant neoplastic transformation was achieved after infection of the rat cholangiocyte cell line, designated BDE1, with the retrovirus Glu664-neu, containing the transforming rat erbB-2/neu oncogene.

Evasion of a single-step, chemotherapy-induced senescence in breast cancer cells: implications for treatment response.

Purpose: The purpose of this study is to define the mechanistic basis for recovery of proliferative capacity in breast tumor cells after chemotherapy. Here, we test the hypothesis that evasion of senescence confers resistance to chemotherapeutic drugs and ionizing radiation.

Experimental Design: MCF-7 cells were treated with a single, clinically relevant dose (0.