A continuous cell line was obtained from the culture of embryonic cells of the cupreous chafer, Anomala cuprea Hope. The cells showed substrate-dependent growth and formed loose networks. Population doubling time was about 4.5 d. The mode of chromosome number was about 32 (4n). The cell line was designated FRI-AnCu-35.

Methods for the stepwise isolation of endothelial cells and smooth muscle cells from individual canine coronary arteries are described. Both cell types can be isolated in pure culture with high yields. Dogs are a common species used in the study of atherosclerosis and coronary artery disease. Capacity to isolate endothelial cells and smooth muscle cells from individual canine coronary arteries should prove useful in the study of coronary artery disease.

Skeletal muscle is a tissue that adapts to increased use by increasing contractile protein gene expression and ultimately skeletal muscle mass (hypertrophy). To identify hypertrophy-inducing agents that may be potentially useful in the treatment of age-related muscle loss (sarcopenia) and to better understand hypertrophy signal transduction pathways, we have created a skeletal muscle cell–based hypertrophy–responsive system. This system was created by permanently modifying the relatively undifferentiated C2C12 cell line so that it contains the β-myosin heavy chain (β-MHC) gene promoter and enhancer regions fused to a luciferase reporter gene. This cell line responds, by increasing luciferase expression, to a variety of skeletal muscle hypertrophy–inducing agents, including insulin, insulin-like growth factor I, testosterone, and the β-adrenergic receptor agonist isoproterenol, in both the undifferentiated and differentiated states. This cell-based system should be useful for identifying novel hypertrophy-inducing agents as well as understanding hypertrophy signal transduction.

The aim of this study was to establish a standard flow cytometric method to measure the phagocytic function of and intracellular hydrogen peroxide (H₂O₂) production by rat leukocytes. Thirty-six adult, male Sprague–Dawley rats were included in this study. Whole-blood specimens from the inferior vena cava were collected in a heparinized tube and ethylenediaminetetraacetic acid (EDTA) anticoagulated tube. The phagocytic function of and intracellular H₂O₂ generation by leukocytes were measured with FACS Vantage™ flow cytometer (Becton Dickinson, San Jose, CA), using fluorescent microspheres and dihydrorhodamine-123 as probes, respectively. Several conditions were optimized in this study, including anticoagulants (heparin and EDTA), fluorescent probes (0.75- and 1.72-μm-diameter microspheres), incubation time, and concentration of the chemicals used in the experiment. Neutrophils, monocytes, and lymphocytes could be clearly defined and separated in whole blood by flow cytometry and tested for phagocytosis and intracellular H₂O₂ generation without the need for further purification and handling of the cells. Intracellular H₂O₂ production by and phagocytic function of neutrophils and monocytes were inhibited in EDTA-anticoagulated blood compared with heparin- anticoagulated blood (P < 0.01). Neutrophils showed similar phagocytic function to 0.75- and 1.72-μm microspheres, but monocytes showed weak phagocytic activity to 1.72-μm beads compared with 0.75-μm beads (P < 0.01). In conclusion, a flow cytometric method to measure the phagocytic function of and intracellular H₂O₂ production by rat leukocytes has been developed. Quantitative flow cytometric analysis of rat leukocyte function is convenient and feasible and provides a reliable and rapid assay to assess phagocytosis and intracellular H₂O₂ production by rat neutrophils and monocytes.

Although expression vectors using viral and mammalian promoters constitutively express genes of interest in adherent cells, few studies have examined whether the function of these vectors in suspended cells, such as in over-agar or soft agar assay (an in vitro cell transformation assay), is as robust as when they are in adherent cells. The selection of appropriate expression vector to optimally express genes in suspended cells would be useful in determining whether these genes play a critical role in maintaining colony formation or cell transformation. To compare promoter-driven expression vector function in adherent versus suspension cells, we performed transient transfection assays using viral (simian virus 40 [SV40] and cytomegalovirus [CMV]) and mammalian (β-actin) promoters fused to luciferase or β-galactosidase reporter gene. Over-agar assay was used to suspend cells on top of agar, which allowed cell retrieval and analysis. We found that β-actin and SV40 promoters exhibited suppressed gene expression of 70 and 56%, respectively, in cells suspended on agar compared with those attached on plates. The suppressed response by the exogenous β-actin promoter in suspension was consistent with the response of the endogenous β-actin promoter activity because the steady-state level of β-actin messenger ribonucleic acid in suspended cells was significantly reduced by 50% relative to that expressed in attached cells. In contrast to SV40 promoter, CMV promoter activity was not decreased in cells suspended in over-agar when compared with adherent cells. These studies show that regardless of mammalian or viral vectors, one cannot assume that all expression vectors behave similarly in both suspension and adherent state.

Polymerase chain reaction (PCR) amplification and deoxyribonucleic acid (DNA) sequence analysis were used to identify the species origin of cell lines used in a cell culture facility where various cell lines of different species are routinely propagated. The aldolase gene family was selected for PCR amplification because the DNA sequences of this gene are highly conserved over a wide range of animals and humans. A total of 36 cell lines representing 13 different species were selected for this study. The DNA from each cell line was amplified, and PCR products were analyzed by agarose gel electrophoresis. The results showed unique profiles of amplified bands on agarose gels that allowed differentiation among non–closely related species. However, DNA amplification of closely related species, including rat and mouse or human and primate, resulted in similar and indistinguishable banding patterns that could be further differentiated by DNA sequence analysis. These results suggested that aldolase gene amplification coupled with DNA sequence analysis is a useful tool for identification of cell lines and has potential application for use in identification of interspecies cross-contamination.

In the lactating breast, the development of secretory alveoli consisting of differentiated cells arranged around a central lumen is dependent on signals from the extracellular environment of the cells. There are few cell lines that model this process. We previously showed that the human breast carcinoma line PMC42-LA can be induced to form organoids, reminiscent of secretory alveoli found in the lactating human breast. In this report, we used high-resolution scanning electron microscopy to show that the formation of organoids is accompanied by development of cell surface microvilli. Extracellular matrix–induced formation of microvilli occurred on the internal and external surfaces of cells in the organoids and not on surfaces in contact with the extracellular matrix. Organoid formation of PMC42-LA cells induced a rearrangement of the extracellular matrix, seen in the form of radiating fibers from the organoids. In summary, there is an interaction between PMC42-LA cells and the underlying extracellular matrix, which leads to the formation of polarized cells with well-developed microvilli. This is accompanied by organization of the extracellular matrix. PMC42-LA is a relevant model of the human breast for investigations into cell–cell and cell–matrix interactions.

Engineered muscle may eventually be used as a treatment option for patients suffering from loss of muscle function. The metabolic and contractile function of engineered muscle has not been well described; therefore, the purpose of this experiment was to study glucose transporter content and glucose uptake in engineered skeletal muscle constructs called myooids. Glucose uptake by way of 2-deoxyglucose and GLUT-1 and GLUT-4 transporter protein content was measured in basal and insulin-stimulated myooids that were engineered from soleus muscles of female Sprague–Dawley rats. There was a significant increase in the basal 2-deoxyglucose uptake of myooids compared with adult control (fivefold), contraction-stimulated (3.4-fold), and insulin-stimulated (threefold) soleus muscles (P = 0.0001, 0.0001, and 0.0001, respectively). In addition, there was a significant increase in the insulin-stimulated 2-deoxyglucose uptake of myooids compared with adult control soleus muscles in basal conditions (6.5-fold) and adult contraction-stimulated (4.5-fold) and insulin- stimulated (3.9-fold) soleus muscles (P = 0.0001, 0.0001, and 0.0001, respectively). There was a significant 30% increase in insulin-stimulated compared with basal 2-deoxyglucose uptake in the myooids. The myooid GLUT-1 protein content was 820% of the adult control soleus muscle, whereas the GLUT-4 protein content was 130% of the control soleus muscle. Myooid GLUT-1 protein content was 6.3-fold greater than GLUT-4 protein content, suggesting that the glucose transport of the engineered myooids is similar in several respects to that observed in both fetal and denervated skeletal muscle tissue.

The existence, origin, and bipotency of the hepatic stem cell (HeSC) have been investigated. However, the isolation and culture of HeSCs from adult liver tissue is not yet well established, and the mechanism by which HeSCs differentiate into mature cells remains unclear. On the other hand, the development of HeSC-isolating and -culturing methods and the in vitro clonal analysis of their mechanism of differentiation are required to enable clinical applications of regenerative medicine in the liver. For the purpose of providing HeSCs for these studies, we attempted to establish an HeSC line from a normal adult porcine liver using a unique culture system, a poly-D-lysine–coated culture dish with NAIR-1 medium (the PDL–NAIR-1 culture system). Moreover, we examined the differentiating capacity of HeSCs in vitro. We demonstrated that it was possible in the culture system that immature epithelial cells capable of proliferating grew selectively into aggregates and that two hepatic stem-like cell lines, PHeSC-A1 and PHeSC-A2, were established. The results from our data suggest that these hepatic stem-like cell lines were capable of self-renewing and differentiating into hepatocytes or biliary epithelial cells and show that the PDL–NAIR-1 culture system offers the immense advantage of isolating and culturing HeSCs from a normal adult liver. Furthermore, because of the ability to use a clonal analysis in vitro, these cell lines are useful for the investigation of various mechanisms in which HeSCs seem to participate and their application in the study of regenerative medicine in the liver.

Although the ES-D3 murine embryonic stem cell line was one of the first derived, little information exists on the in vitro differentiation potential of these cells. We have used immunocytochemical and flow cytometric methods to monitor ES-D3 embryoid body differentiation in vitro during a 21-d period. Spontaneous differentiation of embryoid body cells was induced by leukemia inhibitory factor withdrawal in the absence of feeder cells. The pluripotent stem cell markers Oct-3/4, SSEA-1, and EMA-1 were found to persist for at least 7 d, whereas the primitive endoderm marker cytokeratin endo-A was expressed at increasing levels from day 6. The localization of these antigens within the embryoid bodies suggested that embryonic ectoderm– and primitive endoderm–derived tissues were segregated. Localized expression of class III beta-tubulin and sarcomeric myosin also was detected, indicating that representatives of all three embryonic germ layers were present after induction of differentiation in vitro.

To understand further the effects of spaceflight on osteoblast-enriched cultures, normal chicken calvarial osteoblasts were flown aboard shuttle flight STS-77, and the total number of attached cells was determined. Spaceflight and control cultures were chemically fixed 3 h and 3 d after launch. These fixed cultures were processed for scanning electron microscopy (SEM). The SEM analysis showed that with just 3 d of exposure to spaceflight, coverslip cultures contained 300 ± 100 cells/mm², whereas 1G control samples contained a confluent monolayer of cells (2400 ± 200 cells/mm²). Although the cultures flown in space experienced a drastic decline in cell number in just 3 d, without further experimentation it was impossible to determine whether the decline was a result of microgravity, the harsh launch environment, or some combination of these factors. Therefore, this research attempted to address the effect of launch by subjecting osteoblasts to conditions simulating shuttle launch accelerations, noise, and vibrations. No differences, compared with controls, were seen in the number of total or viable cells after exposure to these various launch conditions. Taken together, these data indicate that the magnitude of gravitational loading (3G maximum) and vibration (7.83G rms maximum) resulting from launch does not adversely affect osteoblasts in terms of total or viable cell number immediately, but launch conditions, or the microgravity environment itself, may start a cascade of events that over several d contributes to cell loss.

Activation of protein kinase c (PKC) reduces transcription from the polymerase III (pol III)–transcribed adenovirus VA gene. Data presented here support a role for PKC in disrupting the formation of transcription-competent initiation complexes. The study used the plasmids VA and VA/EL (VA gene with a linker to distinguish its transcript from that of the VA gene) in in vitro assays to show that preincubation of either template for a minimum of 10 min before the activation of PKC did not result in PKC-induced repression of transcription. In contrast, under the same conditions, efficient transcription occurs from a preincubated template but not from a second template if it is added during or after the activation of PKC. Simultaneous preincubation of both VA and VA/EL resulted in efficient transcription from both templates. Rescue experiments confirm that PKC modifies a target within transcription factor B (TFIIIB) because phosphocellulose fractionation of whole-cell extracts that yield partially purified pol III transcription factor, TFIIIB, successfully rescues VA transcription from PKC-induced repression. Subsequent studies confirmed that the TATA box–binding protein (TBP), a constituent of TFIIIB, substituted for the crude preparation of TFIIIB. These data support a conclusion that activation of PKC triggers a cascade that likely involves the sequestration or degradation of TBP, resulting in the disruption of the steps that leads to successful pol III transcription initiation.

Continuous cell lines are widely used in cell biology and serve as model systems in basic and applied research. Fundamental requirements for the use of cell lines are a well-identified origin and the exclusion of cross-contamination by prokaryotic or eukaryotic cells. Because the cross-contamination of one cell line with another cell line may occur in a concealed manner, special emphasis must be taken to (1) prevent such an “accident” and (2) monitor regularly the identity of the cell line(s) in use. Apart from human cell lines, mouse-, rat-, and hamster-derived cell lines are used in basic cell culture and biotechnology. We established a polymerase chain reaction (PCR) assay to detect and confirm the species origin for these species and to detect interspecies cross-contamination. Our PCR method is based on oligonucleotide primers annealing to specific sequences in the β-globin gene, which were designed to amplify one deoxyribonucleic acid (DNA) segment only per analyzed sample. We confirmed the species identity of 82 cell lines as human, mouse, rat, and Syrian hamster by β-globin PCR. The DNAs from eight additional cell lines of less frequently used species were not amplified with the primers chosen. Cross-contamination of 5–10% of either mouse or rat DNA was detectable. One species-specific primer pair was sufficient for confirmation of the expected species, and for identification of an unknown cell line the combination of two or more primer pairs is suggested. Our PCR assay represents a powerful, fast, easy, robust, and inexpensive method for speciation and does not need any elaborate sequencing or computer-based analysis system.