Cell surface marker and cell cycle analysis, Hedgehog signaling, and flow cytometry.

Detailed cytological analysis of cells undergoing differentiation often reveals clues to the regulation of multiple cell features. The Hedgehog (Hh) signaling cascade is a master regulator of cell fate during differentiation and is implicated in the development of some neoplasias. Hh signaling affects the expression of cell surface markers of differentiation. We have used the flow cytometer to evaluate the effect of blockage of the Hh signal on the expression of cell surface markers of erythroid differentiation in an in vitro system. In addition, the effect of Hh signaling on the distribution of cells in the phases of the cell cycle over the course of erythroid differentiation was assessed. Inhibition of the Hh signal retards progression of the erythroid developmental program. Included is a discussion of some of the basic parameters, limitations, and interpretations of flow cytometric analysis used for CD marker expression and cell cycle studies.

Hedgehog signaling and cell cycle control in differentiating erythroid progenitors.

Hedgehog (Hh) signaling regulates differentiation in numerous systems, but its functions in the control of hematopoietic differentiation have not been extensively explored. Initial studies have indicated that hedgehog signaling affects the proliferation and differentiation of erythroid progenitors (Detmer, K., et al., Erythroid differentiation in vitro is blocked by cyclopamine, an inhibitor of hedgehog signaling. Blood Cells Mol. Dis. 26(4) (2000) 360-372). To examine the effect of Hh signaling on the erythroid developmental program at the molecular level, Hh signaling in committed erythroid progenitors differentiating in vitro was inhibited, and the appearance/disappearance of molecular markers of erythroid differentiation was monitored. The expression timetable for CD34, CD36, the erythropoietin receptor, and glycophorin A was retarded in the absence of Hh signaling. Hemoglobinization was delayed and decreased relative to controls. Morphological changes of erythroid maturation were also delayed. The fraction of cells in S-phase was decreased during the initial period of exponential expansion as assessed by propidium iodide staining and flow cytometry, as was the rate of tritiated thymidine incorporation. A modest decrease in the proliferation rate was observed. These results suggest that Hh signaling is one of the mechanisms in the regulation of erythroid proliferation and differentiation.

Clonogenic analysis reveals reserve stem cells in postnatal mammals. II. Pluripotent epiblastic-like stem cells.

Undifferentiated cells have been identified in the prenatal blastocyst, inner cell mass, and gonadal ridges of rodents and primates, including humans. After isolation these cells express molecular and immunological markers for embryonic cells, capabilities for extended self-renewal, and telomerase activity. When allowed to differentiate, embryonic stem cells express phenotypic markers for tissues of ectodermal, mesodermal, and endodermal origin. When implanted in vivo, undifferentiated noninduced embryonic stem cells formed teratomas. In this report we describe a cell clone isolated from postnatal rat skeletal muscle and derived by repetitive single-cell clonogenic analysis. In the undifferentiated state it consists of very small cells having a high ratio of nucleus to cytoplasm. The clone expresses molecular and immunological markers for embryonic stem cells. It exhibits telomerase activity, which is consistent with its extended capability for self-renewal. When induced to differentiate, it expressed phenotypic markers for tissues of ectodermal, mesodermal, and endodermal origin. The clone was designated as a postnatal pluripotent epiblastic-like stem cell (PPELSC). The undifferentiated clone was transfected with a genomic marker and assayed for alterations in stem cell characteristics. No alterations were noted. The labeled clone, when implanted into heart after injury, incorporated into myocardial tissues undergoing repair. The labeled clone was subjected to directed lineage induction in vitro, resulting in the formation of islet-like structures (ILSs) that secreted insulin in response to a glucose challenge. This study suggests that embryonic-like stem cells are retained within postnatal mammals and have the potential for use in gene therapy and tissue engineering.

Adult reserve stem cells and their potential for tissue engineering.

Tissue restoration is the process whereby multiple damaged cell types are replaced to restore the histoarchitecture and function to the tissue. Several theories have been proposed to explain the phenomenon of tissue restoration in amphibians and in animals belonging to higher orders. These theories include dedifferentiation of damaged tissues, transdifferentiation of lineage-committed progenitor cells, and activation of reserve precursor cells. Studies by Young et al. and others demonstrated that connective tissue compartments throughout postnatal individuals contain reserve precursor cells. Subsequent repetitive single cell-cloning and cell-sorting studies revealed that these reserve precursor cells consisted of multiple populations of cells, including tissue-specific progenitor cells, germ-layer lineage stem cells, and pluripotent stem cells. Tissue-specific progenitor cells display various capacities for differentiation, ranging from unipotency (forming a single cell type) to multipotency (forming multiple cell types). However, all progenitor cells demonstrate a finite life span of 50 to 70 population doublings before programmed cell senescence and cell death occurs. Germ-layer lineage stem cells can form a wider range of cell types than a progenitor cell. An individual germ-layer lineage stem cell can form all cells types within its respective germ-layer lineage (i.e., ectoderm, mesoderm, or endoderm). Pluripotent stem cells can form a wider range of cell types than a single germ-layer lineage stem cell. A single pluripotent stem cell can form cells belonging to all three germ layer lineages. Both germ-layer lineage stem cells and pluripotent stem cells exhibit extended capabilities for self-renewal, far surpassing the limited life span of progenitor cells (50-70 population doublings). The authors propose that the activation of quiescent tissue-specific progenitor cells, germ-layer lineage stem cells, and/or pluripotent stem cells may be a potential explanation, along with dedifferentiation and transdifferentiation, for the process of tissue restoration. Several model systems are currently being investigated to determine the possibilities of using these adult quiescent reserve precursor cells for tissue engineering.

Isoproterenol inhibits transcription of cardiac cytokine genes induced by reactive oxygen intermediates.

BACKGROUND: Cytokines such as tumor necrosis factor alpha (TNF-alpha) are produced by the myocardium in heart disease and might be stimulated by reactive oxygen. In some cell types, cyclic adenosine monophosphate (AMP) inhibits TNF-alpha production. The authors tested the hypothesis that stimulation of cardiac beta-adrenergic receptors would inhibit cytokine gene transcription induced by reactive oxygen. METHODS: Rat hearts were perfused with buffer containing hypoxanthine. Reactive oxygen intermediates were generated by infusion of xanthine oxidase. Myocardial mRNA encoding 11 cytokines was determined. TNF-alpha, interleukin-6, and cyclic AMP were measured in the coronary effluent. RESULTS: In control hearts, of the screened RNA, only mRNA encoding interleukin-1beta, -4, and -6 was detected. Stimulation with hypoxanthine-xanthine oxidase (HX-XO) induced detectable mRNA for TNF-alpha and interleukin-5 and increased mRNA band density for interleukin-1beta, -4, and -6. Simultaneous infusion of isoproterenol inhibited HX-XO-stimulated cytokine gene expression and caused release of cyclic AMP into the coronary effluent. In control hearts, TNF-alpha was not detected in the coronary effluent. After HX-XO administration, TNF-alpha was reliably detected at 60 min and interleukin-6 at 90 min. Simultaneous infusion of isoproterenol inhibited TNF-alpha and interleukin-6 release. Inclusion of propranolol in the perfusion buffer blocked the isoproterenol-induced inhibition of HX-XO-stimulated TNF-alpha release and release of cyclic AMP into the coronary effluent. In addition, elevating myocardial cyclic AMP with forskolin also blocked release of TNF-alpha stimulated by HX-XO. Finally, delaying infusion of isoproterenol until 30 min after HX-XO administration still suppressed release of TNF-alpha. CONCLUSIONS: Reactive oxygen species activate cytokine gene transcription in the myocardium. The sympathetic nervous system, acting through beta-receptors to elevate myocardial cyclic AMP, regulates cardiac cytokine production by inhibition of transcription.

Bone morphogenetic proteins act synergistically with haematopoietic cytokines in the differentiation of haematopoietic progenitors.

We examined the effects of bone morphogenetic protein-2 (BMP-2), -3, -4, -5, -6, and -7 on the proliferation and differentiation of bone marrow CD34+ haematopoietic progenitors in semi-solid medium. The BMPs had no effect on haematopoietic colony development when added to medium containing erythropoietin (Epo) or Interleukin-3 plus Epo. Synergistic effects with the haematopoietic cytokines stem cell factor (SCF) and granulocyte-macrophage colony-stimulating factor (GM-CSF) were observed. In conjunction with GM-CSF and Epo, BMP-4 increased the number of both erythroid and granulocyte/monocyte colonies formed in semi-solid medium (P<0.01). No other BMP stimulated erythroid colony development under these conditions, while BMP-3, BMP-7 (P<0.01), BMP-5, and BMP-6 (P<0.05) stimulated granulocyte/monocyte colony formation. BMP-7 acted synergistically with stem cell factor to increase granulocyte/monocyte colony formation but not erythroid colony formation. The other BMPs did not affect either erythroid or granulocyte/monocyte colony development under these conditions. These results suggest that individual BMPs form part of the complement of cytokines regulating the development of haematopoietic progenitors, and in particular, point to a role for BMP-4 in the control of definitive, as well as embryonic erythropoiesis.

An IkappaB-alpha mutant inhibits cytokine gene expression and proliferation in human vascular smooth muscle cells.

BACKGROUND: Inflammatory reaction and intimal proliferation of smooth muscle cells are characteristics of vascular stenotic lesions. Nuclear factor kappaB (NF-kappaB) is involved in regulation of inflammation and cell survival in a variety of cell types. We tested a hypothesis that selective inhibition of NF-kappaB by expression of a mutated, nondegradable inhibitor of NF-kappaB, IkappaB-alphaM, would inhibit proinflammatory cytokine expression and proliferation in human vascular smooth muscle cell. MATERIALS AND METHODS: Smooth muscle cells were cultured from internal mammary artery and infected with recombinant adenovirus vectors. RESULTS: Adenoviral expression of IkappaB-alphaM inhibited diverse signal-triggered cellular IkappaB-alpha degradation, subsequent NF-kappaB activation, and transactivation of proinflammatory cytokine genes. Expression of IkappaB-alphaM in low-density VSMC led to a 60% reduction in serum-stimulated cell growth and a 10% increment in apoptotic incidence but was without effect in high-density cultures. Coexpression of NF-kappaB p65 attenuated apoptosis in low-density cells induced by IkappaB-alphaM. Therefore, the susceptibility to apoptosis induction in the low-density cells correlated with lower constitutive NF-kappaB activity. The induction of apoptosis by IkappaB-alphaM and the rescue by NF-kappaB p65 might be explained by mutual control of NF-kappaB p65 and IkappaB-alphaM access to the nucleus. CONCLUSION: Our results suggest that expression of nondegradable IkappaB-alpha might have therapeutic potential in both vascular inflammatory reaction and smooth muscle cell proliferation.