Isolation and functional assessment of mouse skeletal stem cell lineage.

There are limited methods available to study skeletal stem, progenitor, and progeny cell activity in normal and diseased contexts. Most protocols for skeletal stem cell isolation are based on the extent to which cells adhere to plastic or whether they express a limited repertoire of surface markers. Here, we describe a flow cytometry-based approach that does not require in vitro selection and that uses eight surface markers to distinguish and isolate mouse skeletal stem cells (mSSCs); bone, cartilage, and stromal progenitors (mBCSPs); and five downstream differentiated subtypes, including chondroprogenitors, two types of osteoprogenitors, and two types of hematopoiesis-supportive stroma. We provide instructions for the optimal mechanical and chemical digestion of bone and bone marrow, as well as the subsequent flow-cytometry-activated cell sorting (FACS) gating schemes required to maximally yield viable skeletal-lineage cells. We also describe a methodology for renal subcapsular transplantation and in vitro colony-formation assays on the isolated mSSCs. The isolation of mSSCs can be completed in 9 h, with at least 1 h more required for transplantation. Experience with flow cytometry and mouse surgical procedures is recommended before attempting the protocol. Our system has wide applications and has already been used to study skeletal response to fracture, diabetes, and osteoarthritis, as well as hematopoietic stem cell-niche interactions in the bone marrow.

Stem cell-derived systems in toxicology assessment.

Industrial sectors perform toxicological assessments of their potential products to ensure human safety and to fulfill regulatory requirements. These assessments often involve animal testing, but ethical, cost, and time concerns, together with a ban on it in specific sectors, make appropriate in vitro systems indispensable in toxicology. In this study, we summarize the outcome of an EPAA (European Partnership of Alternatives to Animal Testing)-organized workshop on the use of stem cell-derived (SCD) systems in toxicology, with a focus on industrial applications. SCD systems, in particular, induced pluripotent stem cell-derived, provide physiological cell culture systems of easy access and amenable to a variety of assays. They also present the opportunity to apply the vast repository of existing nonclinical data for the understanding of in vitro to in vivo translation. SCD systems from several toxicologically relevant tissues exist; they generally recapitulate many aspects of physiology and respond to toxicological and pharmacological interventions. However, focused research is necessary to accelerate implementation of SCD systems in an industrial setting and subsequent use of such systems by regulatory authorities. Research is required into the phenotypic characterization of the systems, since methods and protocols for generating terminally differentiated SCD cells are still lacking. Organotypical 3D culture systems in bioreactors and microscale tissue engineering technologies should be fostered, as they promote and maintain differentiation and support coculture systems. They need further development and validation for their successful implementation in toxicity testing in industry. Analytical measures also need to be implemented to enable compound exposure and metabolism measurements for in vitro to in vivo extrapolation. The future of SCD toxicological tests will combine advanced cell culture technologies and biokinetic measurements to support regulatory and research applications. However, scientific and technical hurdles must be overcome before SCD in vitro methods undergo appropriate validation and become accepted in the regulatory arena.

Isolation and functional assessment of cutaneous stem cells.

The epidermis and associated appendages of the skin represent a multi-lineage tissue that is maintained by perpetual rounds of renewal. During homeostasis, turnover of epidermal lineages is achieved by input from regionalized keratinocytes stem or progenitor populations with little overlap from neighboring niches. Over the last decade, molecular markers selectively expressed by a number of these stem or progenitor pools have been identified, allowing for the isolation and functional assessment of stem cells and genetic lineage tracing analysis within intact skin. These advancements have led to many fundamental observations about epidermal stem cell function such as the identification of their progeny, their role in maintenance of skin homeostasis, or their contribution to wound healing. In this chapter, we provide a methodology to identify and isolate epidermal stem cells and to assess their functional role in their respective niche. Furthermore, recent evidence has shown that the microenvironment also plays a crucial role in stem cell function. Indeed, epidermal cells are under the influence of surrounding fibroblasts, adipocytes, and sensory neurons that provide extrinsic signals and mechanical cues to the niche and contribute to skin morphogenesis and homeostasis. A better understanding of these microenvironmental cues will help engineer in vitro experimental models with more relevance to in vivo skin biology. New approaches to address and study these environmental cues in vitro will also be addressed.

Interlaboratory assessment of a novel colony-forming unit assay: a multicenter study by the cellular team of Biomedical Excellence for Safer Transfusion (BEST) collaborative.

BACKGROUND: Interlaboratory scoring performances were determined using a traditional 14-day colony-forming unit (CFU) assay and a new 7-day CFU assay. STUDY DESIGN AND METHODS: Digital images of colonies were utilized to train personnel at each site. A central laboratory inoculated methylcellulose with progenitors and sent the samples by overnight courier to participating labs for plating. RESULTS: Colony counts from two digital images showed greater variability by novice counters (coefficients of variation [CV], 18.5 and 23.0%; n = 8) than for experienced staff (CV, 7.3 and 4.8%; n = 5). CFU assays plated immediately, 24 and 48 hours after methylcellulose inoculation displayed 39.5 CFU, 37.1 ± 10.6 (CV, 28%) and 34.8 ± 8.5 (CV, 24%) colonies for the 7-day assay and 39.5 CFU, 39.1 ± 9.9 (CV, 25%) and 37.1 ± 10.6 (CV, 28%) colonies for the 14-day assay, respectively. Overall, no significant differences in colony counts were noted between assays (p = 0.68). Also, no differences in CFU counts were seen when assays were set up immediately, 24 and 48 hours after methylcellulose inoculation (14-day p = 0.695; 7-day p = 0.632). CONCLUSION: Total CFUs obtained in 7- and 14-day CFU assays are comparable and show similar levels of interlaboratory variability. The major source of this variability is due to differences in how CFU plates are scored by individuals at different sites. UCB progenitor cells can be maintained in methylcellulose-based media at room temperature for up to 48 hours prior to transport without a significant loss in CFUs.

Factors influencing cord blood viability assessment before cryopreservation.

BACKGROUND: Cord blood (CB) viability determines product quality and varies with time and temperature of exposure before cryopreservation. Global viability assessment may not reflect viability of white blood cell (WBC) subsets, CD34+ cell viability, or hematopoietic stem/progenitor cells function. STUDY DESIGN AND METHODS: We compared trypan blue (TB) and acridine orange/propidium iodide (AO/PI) staining with flow-cytometric (7-aminoactinomycin D [7-AAD]) viability in total WBCs (Tot-AAD), granulocytes, monocytes, lymphocytes, and CD34+ cells and total nucleated cell, CD34+, and colony-forming cell (CFC) recovery as a function of time and temperature (4, 24, and 37 degrees C) before cryopreservation. RESULTS: TB, AO/PI, and Tot-AAD viability was concordant up to 72 hours (4 degrees C) and 48 hours (24 degrees C) postcollection; however, CD34+ viability was significantly higher due to loss of viable granulocytes. In contrast, at "physiologic" temperature (37 degrees C), the decline in TB, AO/PI, and Tot-AAD viability was significantly lower than the rate of viable CD34+ and CFC loss. At all times and temperatures, CFC recovery correlated best with CD34+ viability and recovery. CONCLUSIONS: CB cell populations exhibit differential time- and temperature-dependent susceptibility to in vitro cell death; consequently, global viability measurements using TB, AO/PI, or 7-AAD (Tot-AAD) significantly underestimate (4-24 degrees C) or overestimate (24-37 degrees C) CD34+ viability and CFC recovery. Our results demonstrate the limitations of global viability assessment with TB, AO/PI, and total AAD; endorse the routine use of CD34+ cell viability measurements; emphasize the importance of temperature control during shipment; and have implications with regard to establishing acceptable "cutoff" values for viability measurements and CB collection through processing time.

Assessment of drug induced developmental toxicity using human embryonic stem cells.

Embryonic stem (ES) cells are unique as they have the potential to be generated in large numbers and the ability to differentiate into the three germ layers via embryoid body (EB) formation. This property could be utilized as an index to study initial mammalian development. We have investigated the utility of a comprehensively characterized human ES (hES) cell line (ReliCellhES1) for testing the embryotoxic effects of compounds using cytotoxicity assays. Further, we performed real time gene expression analysis to check the alterations in germ layer markers expression upon drug treatment. The results show that assays using hES cells could serve as a reliable, sensitive and robust method to assess embryotoxic potential of compounds. They also provide a proof of concept that hES cells can be used as an in vitro model to demonstrate developmental toxicity, and to examine the germ layer-specific effects on differentiating EBs.

Deceptive multilineage reconstitution analysis of mice transplanted with hemopoietic stem cells, and implications for assessment of stem cell numbers and lineage potentials.

Hemopoietic stem cells (HSC) are identified through their unique ability, at the single cell level, to long-term reconstitute all blood cell lineages. Sustained myeloid reconstitution is considered the hallmark of HSC, because myeloid progenitors and their progeny have very short half-lives. Here we demonstrate that the established practice of relying on RB6-8C5 as a myeloid specific Ab can result in overestimation of HSC frequencies because the RB6-8C5 Ab also detects Ags expressed on a sizeable population of CD3(+)CD8(+) T cells, constitutively as well as following transplantation. Likewise, a high fraction of mice transplanted with limiting numbers of ex vivo expanded Lin(-)Sca(+)kit(+)CD34(-) HSC show long-term RB6-8C5(+)CD3(+) (lymphoid) but no RB6-8C5(+)CD3(-) (myeloid) reconstitution. Most noteworthy, the use of RB6-8C5 as a myeloid specific Ab can be deceptive by implicating the existence of lineage-restricted HSC capable of long-term reconstituting the myeloid and T, but not B, cell lineage. Because cross-lineage expression of "lineage-specific" markers is unlikely to be unique to the blood system, claims of unexpected cell fates should be substantiated not only by acquisition of lineage-specific markers, but also absence of markers of other lineages normally derived from the investigated stem cells.

Rat granulocyte colony-forming unit (CFU-G) assay for the assessment of drug-induced hematotoxicity.

To assess the drug-induced hematotoxicity to granulocyte progenitors, we established a modified colony-forming assay using rat bone marrow cells (BMCs). In the presence of various colony-stimulating factors (CSFs), rat BMCs were disseminated on methylcellulose at a concentration of 1.3 x 10(4) cells/cm(2) (5 x 10(4) cells/0.5 ml/well in a 12-well plate). Mouse granulocyte-macrophage colony-stimulating factor (mGM-CSF) stimulated the formation of almost all macrophage colonies. Human granulocyte colony-stimulating factor (hG-CSF) alone or in combination with mouse interleukin-3 (mIL-3) did not significantly effect on the number of rat colony-forming units in culture (CFU-C). When BMCs were seeded at 5.2 x 10(4) cells/cm(2) (5 x 10(5) cells/1 ml/dish in a 35-mm dish), hG-CSF increased the number of the colonies in a dose-dependent manner, and resulted in about 50 colonies at 50 ng/ml. The constituent cells of the colonies were identified as neutrophils. Under these conditions, the effects of 5-fluorouracil (5-FU) on granulocyte colony-forming units (CFU-G) were examined in rats and mice. The inhibitory effect of 5-FU on rat CFU-G was similar to the effect on mouse CFU-G. These results indicate that the rat CFU-G induced by hG-CSF is capable of being used for the evaluation of drug-induced hematotoxicity.

A cost-effective method for the automatic quantitative analysis of fibroblastic colony-forming units.

A great deal of the work characterizing stromal cell precursors in the bone marrow has been performed using the fibroblastic colony-forming unit (CFU-f) assay. However, the assay is limited in its usefulness by the necessity for manual colony counting which means that assay quantitation is highly subjective, time consuming, and much information regarding the colony size is lost. To rectify this, we have developed a computer-automated method for the analysis of CFU-f. Bone marrow cells were cultured at low density and treated with either prostaglandin E(2) (PGE(2)), basic fibroblast growth factor (bFGF), or dexamethasone, and colony formation was assessed by staining with methylene blue. After staining, the dishes were photographed over a light box using a digital camera and the image was then analyzed using Bioimage "Intelligent Quantifier" image analysis software which automatically locates and quantifies each individual colony. The data can then be imported to a spreadsheet program and processed. We have shown that this system can accurately identify, assign coordinates, and quantitate each individual colony. Colony numbers obtained with this method and manually counting showed a linear relationship with a correlation coefficient of 0.99. In addition, using the colony intensity and surface area data, the colony size can be calculated. With this methodology, we have shown that dexamethasone, PGE(2), and bFGF can all modulate total cell numbers in bone marrow stromal cells (BMSC) cultures but modulating both colony number and colony size.

A histological assessment of the four-day subrenal capsule assay (SRCA).

A four-day subrenal capsule assay (SRCA) was developed, since fragments of human tumours implanted under the renal capsule of immunocompetent mice became rejected by the host within six days. The assay requires a histological assessment of both its exploitability and the extent of drug-induced anti-tumour lesions. 45 tumours from 43 patients with solid tumour were submitted to an SRCA in 1410 male B6D2F1 mice. After being biopsied each tumour was dissected by a pathologist, cut into 50 pieces (1.5 mm3), and one piece was implanted under the renal capsule of 35 mice; the mean tumour diameter was measured on day 0. The mice were randomized into groups of 6 to 10 animals each. On days 1, 2 and 3, the mice were treated with either placebo (control group) or with various anticancer agents. On day 4 the animals were sacrificed, the mean tumour diameter measured, the tumour bearing kidney fixed in Bouin's picroformol solution and processed for histological analysis after staining with hematein. Fragments of fresh explants of human tumours retained their proliferative and metabolic capacity: mitoses were observed as well as keratinizing cells in epidermoid carcinomas and melanin-producing cells in melanomas. Proliferation of tumour cells was seen along the renal capsule suggesting their affinity for connective tissue. Capillaries filled with mouse erythrocytes were also seen. No or minimal lymphocytic infiltration was found. Drug oncolytic effects ranged from minor cellular degeneration to almost complete necrosis and were documented by the scoring of histologic lesions.(ABSTRACT TRUNCATED AT 250 WORDS)