Dynamic Phenotypic Changes Research Articles

Plastic induction of CD133AC133-positive cells in the microenvironment of glioblastoma spheroids.

Recent studies showed that the stemness of cancer stem cells is maintained under a hypoxic microenvironment. However, the relationship of the hypoxic microenvironment in a three-dimensional cell mass and the induction of cancer stem cell-like phenotype is not well known. We examined the relationship between CD133 expression and the hypoxic microenvironment using glioblastoma spheroids formed with the T98G cell line. CD133(AC133)- and HIF-1α-positive cells were observed in the marginal region of the central hypoxic area positive for HIF-1α 10 days after plating T98G cells. CD133(AC133)-positive cells were positive for nestin. Quantitative PCR analysis showed that the CD133 expression level is not different in spheroids during the tested period after spheroid formation, indicating that post-translational regulation of the CD133 protein mediates positivity to CD133(AC133). When spheroids were trypsinized and the dissociated cells were cultured under the adherent monolayer conditions, the CD133(AC133)-positive cells gradually disappeared. These results show that CD133(AC133)-positive cells, which may incline toward undifferentiated cells because of nestin positivity, are plastically induced under the different culture conditions, spheroid and monolayer. In this plasticity, HIF-1α is involved in the induction and maintenance of CD133(AC133)-positive cells. Spheroids as an in vitro tumor model are useful to study the dynamic changes in the tumor cell phenotype in the different cell microenvironments.

Quantification of dynamic morphological drug responses in 3D organotypic cell cultures by automated image analysis.

Glandular epithelial cells differentiate into complex multicellular or acinar structures, when embedded in three-dimensional (3D) extracellular matrix. The spectrum of different multicellular morphologies formed in 3D is a sensitive indicator for the differentiation potential of normal, non-transformed cells compared to different stages of malignant progression. In addition, single cells or cell aggregates may actively invade the matrix, utilizing epithelial, mesenchymal or mixed modes of motility. Dynamic phenotypic changes involved in 3D tumor cell invasion are sensitive to specific small-molecule inhibitors that target the actin cytoskeleton. We have used a panel of inhibitors to demonstrate the power of automated image analysis as a phenotypic or morphometric readout in cell-based assays. We introduce a streamlined stand-alone software solution that supports large-scale high-content screens, based on complex and organotypic cultures. AMIDA (Automated Morphometric Image Data Analysis) allows quantitative measurements of large numbers of images and structures, with a multitude of different spheroid shapes, sizes, and textures. AMIDA supports an automated workflow, and can be combined with quality control and statistical tools for data interpretation and visualization. We have used a representative panel of 12 prostate and breast cancer lines that display a broad spectrum of different spheroid morphologies and modes of invasion, challenged by a library of 19 direct or indirect modulators of the actin cytoskeleton which induce systematic changes in spheroid morphology and differentiation versus invasion. These results were independently validated by 2D proliferation, apoptosis and cell motility assays. We identified three drugs that primarily attenuated the invasion and formation of invasive processes in 3D, without affecting proliferation or apoptosis. Two of these compounds block Rac signalling, one affects cellular cAMP/cGMP accumulation. Our approach supports the growing needs for user-friendly, straightforward solutions that facilitate large-scale, cell-based 3D assays in basic research, drug discovery, and target validation.

A time course investigation of the statin paradox among valvular interstitial cell phenotypes

Statin drugs are prescribed primarily for their ability to lower cholesterol, but may also exert beneficial side effects unrelated to cholesterol metabolism. Previous work has described a "statin paradox," where statin treatment decreased osteoblastic markers in valve myofibroblasts while increasing those same markers in preosteoblasts. However, valvular interstitial cells (VICs) themselves are a multipotent cell type, capable of differentiating into activated, myofibroblastic VICs (aVICs) and osteoblastic VICs (obVICs), motivating the question of whether the statin paradox can exist within an individual valve containing these phenotypically distinct VIC subpopulations. In the current study, a heterogeneous initial population of porcine VICs was differentiated into aVICs or obVICs and treated with simvastatin. Gene expression analysis was conducted daily over an 8-day time course to capture temporally dynamic changes in cell phenotype induced by statin treatment. These studies demonstrated that the two VIC populations, aVICs and obVICs, exhibited differential responses to statin treatment. Specifically, simvastatin increased the expression of osteoblastic markers in obVICs, but not in aVICs, while also suppressing the myofibroblastic phenotype in both aVICs and obVICs. These results indicate that the statin paradox can exist within the heterogeneous VIC population of an individual diseased valve and that statin efficacy in the context of calcific aortic valve disease (CAVD) may be dependent upon the cellular composition of the valve. These findings may have implications for clinical usage of statins, shedding light on how statin efficacy in CAVD may be dependent upon the disease stage or why some individuals exhibit better responsiveness to statin therapy.

Microultrasound and Its Application to Longitudinal Studies of Mouse Eye Development and Disease

Microultrasound imaging is a flexible high-resolution real-time in vivo imaging modality based on the transmission and the reception of ultrasound waves. Because of its high temporal (>250 Hz) and spatial (30-150 µm) resolutions and the noninvasive nature of ultrasound, microultrasound is used extensively in preclinical research to monitor functional and dynamic phenotypic changes in small animal models. Its ability to perform in vivo longitudinal monitoring of development, pathology, and therapeutic effectiveness is particularly advantageous. This article reviews the technology and the applications of high-frequency microultrasound for the study of mouse eye development from embryonic day E11.5 to postnatal day P16. Procedures for animal handling and scanning are given, and applications are described in the context of ocular development and disease. Quantitative analysis of the growth kinetics of the lens and the orbit is discussed. In addition, mouse models of retinoblastoma and glaucoma are followed as a function of disease progression to reveal their associated morphological and functional traits. Microultrasound is performed with high-frequency imaging equipment (from VisualSonics) operating at center frequencies between 15 and 50 MHz. These instruments provide both anatomical imaging as well as functional and molecular analyses of the living mouse.

Effects of Irradiation on Growth and Differentiation-Related Gene Expression in Osteoblasts

Osteoblasts are bone-forming cells that are responsible for the production of bone extracellular matrix. Osteoradionecrosis is a complication of radiation therapy for carcinoma of the head and neck that occurs in 3% to 8.2% of irradiated patients. The irradiation effect on osteoblast differentiation has not been fully elucidated. The objective of our research was to elucidate the effects of radiation on the growth and differentiation-related gene expression in osteoblast in vitro. Three differentiation-related genes, alkaline phosphatase, type I collagen, and osteocalcin, were tested in our experiment. The results showed that radiation inhibited the proliferation of the osteoblasts in a dose-dependent manner and induced G2/M cell cycle arrest. Irradiation, 4 and 8 Gy, enhanced the differentiation-related gene expression of MC3T3-E1 cells 7 days after irradiation. However, the differentiation-related gene expression was decreased 21 days after irradiation in the 4- and 8-Gy groups. This work presents the dynamic phenotypic expression changes of osteoblastic cells after x-ray irradiation.

Dynamic molecular changes associated with epithelial–mesenchymal transition and subsequent mesenchymal–epithelial transition in the early phase of metastatic tumor formation

Metastatic tumor formation via vessel route begins with cancer cell extravasation from vessel lumen, migration into the connective tissue surrounding vessels, and invasion into target organ parenchyma. Epithelial-mesenchymal transition (EMT) and mesenchymal-epithelial transition (MET) have been recognized to play an important role in metastatic process, however, how and where these biological changes take place in the early phase of metastatic tumor development has never been clarified. We morphologically evaluated 34 small intrapulmonary metastases formed after cancer cell extravasation from lymphatics (lymphogenic metastasis) and 40 formed in the absence of extravasation (aerogenous metastasis) in human specimens and found that isolated or small clusters of invasive cancer cells (tumor budding) were frequently observed in lymphogenic metastasis (24/34; 71%), but were never observed within aerogenous metastasis. We immunostained 34 lymphogenic metastases for 13 molecular markers of EMT and MET and scored the immunostaining intensity of cancer cells floating in lymphatic vessels (LVs), migrating into the connective tissue surrounding vessels [bronchovascular bundle (BVB)], and growing in lung parenchyma (LP). Cancer cells within BVBs stained more weakly for E-cadherin (p < 0.001), β-catenin (p < 0.001), and Geminin (p < 0.001) and more strongly for MMP-7 (p = 0.046) and Laminin-5 γ2 (p = 0.037) than tumor cells in LVs. However, cancer cells in LP exhibited resurgent E-cadherin (p = 0.011), β-catenin (p < 0.001), and Geminin (p = 0.037) expression and reduced MMP-7 (p = 0.038) and Laminin-5 γ2 (p = 0.001) expression in comparison with cancer cells in BVBs. Our results suggested that in the early phase of metastatic tumor formation cancer cells undergo dynamic phenotypic change associated with EMT and subsequent MET.

Analysis of CD14 Expression Levels in Putative Mesenchymal Progenitor Cells Isolated from Equine Bone Marrow

A long-term goal of mesenchymal progenitor cell (MPC) research is to identify cell-surface markers to facilitate MPC isolation. One reported MPC feature in humans and other species is lack of CD14 (lipopolysaccharide receptor) expression. The aim of this study was to evaluate CD14 as an MPC sorting marker. Our hypothesis was that cells negatively selected by CD14 expression would enrich MPC colony formation compared with unsorted and CD14-positive fractions. After validation of reagents, bone marrow aspirate was obtained from 12 horses. Fresh and cultured cells were analyzed by flow cytometry and reverse transcription and quantitative polymerase chain reaction to assess dynamic changes in phenotype. In fresh samples, cells did not consistently express protein markers used for lineage classification. Short-term (2-day) culture allowed distinction between hematopoietic and nonhematopoietic populations. Magnetic activated cell sorting was performed on cells from 6 horses to separate adherent CD14(+) from CD14(-) cells. MPC colony formation was assessed at 7 days. Cells positively selected for CD14 expression were significantly more likely to form MPC colonies than both unsorted and negatively selected cells (P ≤ 0.005). MPCs from all fractions maintained low levels of CD14 expression long term, and upregulated CD14 gene and protein expression when stimulated with lipopolysaccharide. The equine CD14 molecule was trypsin-labile, offering a plausible explanation for the discrepancy with MPC phenotypes reported in other species. By definition, MPCs are considered nonhematopoietic because they lack expression of molecules such as CD14. Our results challenge this assumption, as equine MPCs appear to represent a descendant of a CD14-positive cell.

Depletion of kidney CD11c+ F4/80+ cells impairs the recovery process in ischaemia/reperfusion-induced acute kidney injury

Recent studies provided evidence of the potential role of CD11c(+) F4/80(+) dendritic subset in mediating injury and repair. The purpose of this study was to examine the role of kidney CD11c(+) F4/80(+) dendritic subset in the recovery phase of ischaemia/reperfusion injury (IRI). Following ischaemia/reperfusion (I/R), liposome clodronate or phosphate buffered saline (PBS) was administered, and on day 7 biochemical and histologic kidney damage was assessed. Activation and depletion of CD11c(+) F4/80(+) dendritic subset were confirmed by flow cytometry. Isolation of kidney CD11c(+) cells on days 1 and 7 with in vitro culture for measuring cytokines was performed to define functional characteristics of these cells, and adoptive transfer of CD11c(+) cells was also done. Following kidney IRI, the percentage of CD11c(+) F4/80(+) kidney dendritic cell subset that co-expresses maturation marker increased. Liposome clodronate injection after I/R resulted in preferential depletion of CD11c(+) F4/80(+) kidney dendritic subset, and depletion of these cells was associated with persistent kidney injury, more apoptosis, inflammation and impaired tubular cell proliferation. CD11c(+) F4/80(+) cell depletion was also associated with higher tissue levels of pro-inflammatory cytokines and lower level of IL-10, indicating the persistence of inflammatory milieu. Isolated kidney CD11c(+) cells on day 7 showed different phenotype with increased production of IL-10 compared with those on day 1. Adoptive transfer of CD11c(+) cells partially reversed impaired tissue recovery. Our results suggest that kidney CD11c(+) F4/80(+) dendritic subset might contribute to the recovery process by dynamic phenotypic change from pro-inflammatory to anti-inflammatory with modulation of immune response.

Temporal alterations in cardiac fibroblast function following induction of pressure overload

Increases in cardiovascular load (pressure overload) are known to elicit ventricular remodeling including cardiomyocyte hypertrophy and interstitial fibrosis. While numerous studies have focused on the mechanisms of myocyte hypertrophy, comparatively little is known regarding the response of the interstitial fibroblasts to increased cardiovascular load. Fibroblasts are the most numerous cell type in the mammalian myocardium and have long been recognized as producing the majority of the myocardial extracellular matrix. It is only now becoming appreciated that other aspects of fibroblast behavior are important to overall cardiac function. The present studies were performed to examine the temporal alterations in fibroblast activity in response to increased cardiovascular load. Rat myocardial fibroblasts were isolated at specific time-points (3, 7, 14, and 28 days) after induction of pressure overload by abdominal aortic constriction. Bioassays were performed to measure specific parameters of fibroblast function including remodeling and contraction of 3-dimensional collagen gels, migration, and proliferation. In addition, the expression of extracellular matrix receptors of the integrin family was examined. Myocardial hypertrophy and fibrosis were evident within 7 days after constriction of the abdominal aorta. Collagen gel contraction, migration, and proliferation were enhanced in fibroblasts from pressure-overloaded animals compared to fibroblasts from sham animals. Differences in fibroblast function and protein expression were evident within 7 days of aortic constriction, concurrent with the onset of hypertrophy and fibrosis of the intact myocardium. These data provide further support for the idea that rapid and dynamic changes in fibroblast phenotype accompany and contribute to the progression of cardiovascular disease.

Phenotypic changes of human cells in human-rat liver during partial hepatectomy-induced regeneration

To examine the human hepatic parenchymal and stromal components in rat liver and the phenotypic changes of human cells in liver of human-rat chimera (HRC) generated by in utero transplantation of human cells during partial hepatectomy (PHx)-induced liver regeneration. Human hepatic parenchymal and stromal components and phenotypic changes of human cells during liver regeneration were examined by flow cytometry, in situ hybridization and immunohistochemistry. ISH analysis demonstrated human Alu-positive cells in hepatic parenchyma and stroma of recipient liver. Functional human hepatocytes generated in this model potentially constituted human hepatic functional units with the presence of donor-derived human endothelial and biliary duct cells in host liver. Alpha fetoprotein (AFP)(+), CD34(+) and CD45(+) cells were observed in the chimeric liver on day 10 after PHx-induced liver regeneration and then disappeared in PHx group, but not in non-PHx group, suggesting that dynamic phenotypic changes of human cells expressing AFP, CD34 and CD45 cells may occur during the chimeric liver regeneration. Additionally, immunostaining for human proliferating cell nuclear antigen (PCNA) showed that the number of PCNA-positive cells in the chimeric liver of PHx group was markedly increased, as compared to that of control group, indicating that donor-derived human cells are actively proliferated during PHx-induced regeneration of HRC liver. HRC liver provides a tool for investigating human liver regeneration in a humanized animal model.

Adipose Tissue Lymphocytes and Macrophages in Obesity and Insulin Resistance

Obesity, and more specifically accumulation of adipose tissue in the visceral and subcutaneous abdominal locations, is a major risk factor for the development of cardiovascular pathologies including hypertension and atherosclerosis, as well as metabolic disorders such as type 2 diabetes. During recent years, “metaflammation” or metabolically-triggered inflammation1 has emerged as a key process involved in the clustering of those conditions. Although several metabolically active organs such as the liver, muscle, and, recently, the intestine2 certainly play major roles, the white adipose tissue appears as a central and primary player as both a source and site of inflammation. Accumulation of adipose tissue macrophages (ATMs) has been well-described in obese conditions in mice and humans.3–5 Moreover, the ATM proinflammatory phenotype has been linked to the development of insulin resistance in mice,4 although the exact nature of the proinflammatory myeloid cells, ie, macrophages or dentritic cells, remains to be determined.6 Nevertheless, the causal link between inflammation and insulin resistance was further strengthened by the specific knock-out of the inflammation coordinator IkappaB kinase beta of myeloid cells, which gave protection against insulin resistance.7 The study of Kintscher and al in this issue8 extends those original observations to cells of adaptative immunity. The authors suggest that the accumulation of T-lymphocytes, assessed mainly through gene expression analyses and immunohistochemistry, occurs in the perigonadal adipose tissue of mice on …

Dynamic changes in conjunctival dendritic cell numbers, anatomical position and phenotype during experimental allergic conjunctivitis

Dendritic cells (DCs) are a subset of antigen-presenting cells (APCs) that are involved in the initiation and control of the immune response to antigens present at the interface with the environment. A limited number of groups have studied DCs in human and animal conjunctiva but no data is available concerning the different DC subsets present in the conjunctival tissue. The aims of this study are to characterize the phenotypes and numbers of DCs present in the murine model of allergic conjunctivitis using the technique of immunohistochemistry so as to aid the understanding of the mechanisms involved in allergic eye disease. A double immunofluorescence method was used to analyze the phenotypic distribution and density of DC subsets in the mouse conjunctival tissues of the allergic model using a panel of antibodies: CD11c, as a general marker of DCs, coupled with another DC subset marker such as Langerin for Langerhans cells (LCs), CD11b for myeloid DCs (mDCs) and mPDCA-1 for plasmacytoid DCs (pDCs). In the naïve conjunctiva, mDCs were consistently detected in the subepithelial layer and substantia propria. In the epithelium and the subepithelial layer, very few LCs and virtually no pDCs were observed. Following allergen challenge, there was a marked influx of mDCs and pDCs, but no LCs, into the subepithelial layer and throughout the substantia propria. These results indicate that conjunctival DC subsets may play an important role in the immune-regulatory processes involved in the inflammatory component of allergic conjunctivitis.

Characterization of a flocculation-like phenotype in Cryptococcus neoformans and its effects on pathogenesis

We investigated the phenomenon of cell-cell aggregation (flocculation) in a serotype D strain of Cryptococcus neoformans (ATCC 24067, isolate RC-2). Cell aggregation into clumps of 5-40 cells (clump+ cells) occurred during the early log phase and disappeared in the beginning of the stationary phase (clump- cells). The cell aggregation phenomenon was medium dependent. Clump+ cells could be dispersed by either vortexing or proteinase K digestion. Most importantly, the transient change in cellular phenotype changed several important host-pathogen interactions. Adherence of clump+ cells to murine macrophage-like cells J774.16 was significantly (P < 0.001) enhanced compared with adherence of clump- cells. Furthermore, complement-mediated phagocytosis efficacy of dispersed clump+ cells was significantly higher (P < 0.001) compared with clump- cells. Similar findings were documented with an in vivo phagocytosis assay. Infection of mice with a low inoculum (10(4)) of clump+ cells resulted in lower fungal burden when compared with mice infected with clump- cells. Accordingly, mice infected with clump+ cells survived significantly longer than mice infected with clump- cells. These results indicate that the cellular phenotype undergoes significant changes that result in a transient flocculation-like phenotype. We hypothesize that this cell-cell aggregation is the result of changes in protein content in the polysaccharide capsule. We conclude from our data that the change in cellular phenotype has a dramatic effect on cell adherence, and on complement-mediated phagocytosis, both of which can affect the pathogenesis of the disease in the host. Our results underscore the complexity of studies that investigate host pathogen interactions and may explain differences and inconsistencies observed in in vitro and in vivo assays.

Developmental Changes in Levels of Proopiomelanocortin Intron A-Containing Heterogeneous Nuclear RNA and Mature Messenger RNA in the Anterior and Neurointermediate Lobes of the Rat Pituitary

The POMC cells of the rat pituitary undergo dynamic phenotypic changes during differentiation. Here we have determined that alterations in the relative levels of a POMC precursor RNA species and POMC mRNA occur during development and may represent another level at which the POMC phenotype is developmentally regulated. We performed solution hybridization/nuclease protection assays using a POMC exon 1/intron A splice junction probe to quantitate levels of both intron A-containing POMC heterogeneous nuclear (hnRNA) and fully processed POMC mRNA in separated anterior and neurointermediate lobes of the fetal, neonatal, and adult pituitary. The levels of POMC hnRNA per anterior lobe increased 7-fold from embryonic day 15 to adulthood (0.022 to 0.159 fmol/lobe), while POMC mRNA levels increased 121-fold (0.15 to 18.2 fmol/lobe). POMC hnRNA levels per neurointermediate lobe increased 23-fold from embryonic day 18 to adulthood (0.024 to 0.54 fmol/lobe), while POMC mRNA levels increased 69-fold (0.65 to 44.6 fmol/lobe). Thus, both anterior and neurointermediate lobes contain higher relative abundances of POMC hnRNA compared to mRNA during early development. These subsequently decrease (from 1:7 to 1: approximately 110 in the anterior lobe and from 1:27 to 1:83 in the intermediate lobe over the ages examined) as the levels of POMC mRNA in both anterior and neurointermediate lobe increase at a greater rate than POMC hnRNA as development progresses. These results provide the first measurements of POMC mRNA and hnRNA levels during ontogeny and suggest that there may be a developmental change in the regulation of POMC primary transcript processing.